Delegated regulation 2014/1322 - Supplement to and amending Regulation 167/2013 with regard to vehicle construction and general requirements for the approval of agricultural and forestry vehicles - Main contents

COMMISSION DELEGATED REGULATION (EU) No 1322/2014

of 19 September 2014

supplementing and amending Regulation (EU) No 167/2013 of the European Parliament and of the Council with regard to vehicle construction and general requirements for the approval of agricultural and forestry vehicles

(Text with EEA relevance)

THE EUROPEAN COMMISSION,

Having regard to the Treaty on the Functioning of the European Union,

Having regard to Regulation (EU) No 167/2013 of the European Parliament and of the Council of 5 February 2013 on the approval and market surveillance of agricultural and forestry vehicles (1), and in particular Articles 18(4), 20(8), 27(6), 28(6), 49(3), 53(12) and 60(1) and Articles 61 and 70 thereto,

Whereas:

HAS ADOPTED THIS REGULATION:

CHAPTER I

SUBJECT MATTER AND DEFINITIONS

Article 1

Subject matter

This Regulation establishes the detailed technical requirements and test procedures regarding vehicle design, construction and assembly for the approval of agricultural and forestry vehicles and their systems, components and separate technical units, the detailed arrangements and requirements with regard to type-approval procedures, virtual testing and conformity of production, the technical specifications with regard to access to repair and maintenance information and the performance standards and criteria for the assessment of technical services in accordance with Regulation (EU) No 167/2013.

Article 2

Definitions

The following definitions shall apply:

CHAPTER II

VEHICLE CONSTRUCTION AND GENERAL TYPE-APPROVAL REQUIREMENTS

Article 3

Manufacturer’s general obligations regarding vehicle construction

• 1. 

  Manufacturers shall equip agricultural and forestry vehicles with systems, components and separate technical units affecting occupational safety that are designed, constructed and assembled so as to enable the vehicle in normal use and maintained according to the prescriptions of the manufacturer to comply with the detailed technical requirements and testing procedures set out in Articles 4 to 32.

• 2. 

  Manufacturers shall demonstrate by means of physical demonstration testing to the approval authority that the agricultural and forestry vehicles made available on the market, registered or entering into service in the Union comply with the detailed technical requirements and test procedures laid down in Articles 4 to 32.

• 3. 

  Manufacturers shall ensure that spare parts and equipment that are made available on the market or are entering into service in the Union comply with the detailed technical requirements and test procedures referred to in this Regulation. An approved agricultural and forestry vehicle equipped with such a spare part or equipment shall meet the same test requirements and performance limit values as a vehicle equipped with an original part.

• 4. 

  Manufacturers shall ensure that type-approval procedures for verifying conformity of production are followed as regards the detailed vehicle construction requirements laid down in this Regulation.

Article 4

Application of UNECE regulations

The UNECE regulations and amendments thereto set out in Annex I to this Regulation shall apply to type-approval of agricultural and forestry vehicles subject to the conditions laid down in this Regulation.

Article 5

Recognition of test reports issued on the basis of OECD Codes for the purposes of EU type-approval

In accordance with Article 50 of Regulation (EU) No 167/2013, the test reports issued on the basis of OECD Codes set out in Annex II to this Regulation shall be recognised for the purpose of EU type approval as an alternative to the test report issued on the basis of this Regulation.

Article 6

Arrangements with regard to type-approval procedures, including the requirements relating to virtual testing

The arrangements with regard to type-approval procedures referred to in Article 20 (8) of Regulation (EU) No 167/2013 and the requirements relating to virtual testing referred to in Article 27(6) of that Regulation shall be laid down in Annex III to this Regulation.

Article 7

Arrangements with regard to conformity of production

The arrangements with regard to conformity of production referred to in Article 28(6) of Regulation (EU) No 167/2013 shall be laid down in Annex IV to this Regulation.

Article 8

Requirements with regard to access to repair and maintenance information

The requirements with regard to access to repair and maintenance information referred to in Article 53(12) of Regulation (EU) No 167/2013 shall be laid down in Annex V to this Regulation.

Article 9

Requirements applying to roll-over protection structures (dynamic testing)

The test procedures and requirements applying to roll-over protection structures as regards dynamic testing for vehicles of categories T1, T4.2 and T4.3 referred to in Article 18(2)(a) of Regulation (EU) No 167/2013 shall be conducted and verified in accordance with Annex VI to this Regulation.

Article 10

Requirements applying to roll-over protection structures (track-laying tractors)

The test procedures and requirements applying to roll-over protection structures as regards track-laying tractors for vehicles of categories C1, C2, C4.2 and C4.3 referred to in Article 18(2)(a) of Regulation (EU) No 167/2013 shall be conducted and verified in accordance with Annex VII to this Regulation.

Article 11

Requirements applying to roll- over protection structures (static testing)

As an alternative to the requirements laid down in Article 9 and Article 10, manufacturers may choose to comply with the requirements of this Article, where the type of vehicle falls within the field of application set out in Annex VIII to this Regulation. The test procedures and requirements applying to roll-over protection structures as regards static testing for vehicles of categories T1/C1, T4.2/C4.2 and T4.3/C4.3 referred to in Article 18(2)(a) of Regulation (EU) No 167/2013 shall be conducted and verified in accordance with Annex VIII to this Regulation.

Article 12

Requirements applying to roll-over protection structures (front mounted roll-over protective structures on narrow-track tractors)

The test procedures and requirements applying to front mounted roll-over protective structures as regards narrow- track tractors for vehicles of categories T2, T3 and T4.3 referred to in Article 18(2)(a) of Regulation (EU) No 167/2013 shall be conducted and verified in accordance with Annex IX to this Regulation.

Article 13

Requirements applying to roll-over protection structures (rear mounted roll-over protective structures on narrow-track tractors)

The test procedures and requirements applying to rear mounted roll-over protective structures as regards narrow-track tractors for vehicles of categories T2/C2, T3/C3 and T4.3/C4.3 referred to in Article 18(2)(a) of Regulation (EU) No 167/2013 shall be conducted and verified in accordance with Annex X to this Regulation.

Article 14

Requirements applying to falling objects protection structures

The test procedures and requirements applying to falling objects protection structures for vehicles of categories T and C referred to in Article 18(2)(b) of Regulation (EU) No 167/2013 shall be conducted and verified in accordance with Annex XI to this Regulation.

Article 15

Requirements applying to passenger seats

The test procedures and requirements applying to passenger seats for vehicles of categories T and C referred to in Article 18(2)(c) of Regulation (EU) No 167/2013 shall be conducted and verified in accordance with Annex XII to this Regulation.

Article 16

Requirements applying to the driver’s exposure to noise level

The test procedures and requirements applying to the driver’s exposure to noise level for vehicles of categories T and C referred to in Article 18(2)(d) of Regulation (EU) No 167/2013 shall be conducted and verified in accordance with Annex XIII to this Regulation.

Article 17

Requirements applying to the driving seat

The test procedures and requirements applying to the driving seat for vehicles of categories T and C referred to in Article 18(2)(e) of Regulation (EU) No 167/2013 shall be conducted and verified in accordance with Annex XIV to this Regulation.

Article 18

Requirements applying to operating space and to access to the driving position

The test procedures and requirements applying to operating space and to access to the driving position for vehicles of categories T and C referred to in Article 18(2)(f) of Regulation (EU) No 167/2013 shall be conducted and verified in accordance with Annex XV to this Regulation.

Article 19

Requirements applying to power take-offs

The test procedures and requirements applying to power take-offs for vehicles of categories T and C referred to in Article 18(2)(g) of Regulation (EU) No 167/2013 shall be conducted and verified in accordance with Annex XVI to this Regulation.

Article 20

Requirements applying to the protection of drive components

The test procedures and requirements applying to protection of drive components for vehicles of categories T and C referred to in Article 18(2)(h) of Regulation (EU) No 167/2013 shall be conducted and verified in accordance with Annex XVII to this Regulation.

Article 21

Requirements applying to seat-belt anchorages

The test procedures and requirements applying to seat-belt anchorages for vehicles of categories T and C referred to in Article 18(2)(i) of Regulation (EU) No 167/2013 shall be conducted and verified in accordance with Annex XVIII to this Regulation.

Article 22

Requirements applying to safety belts

The test procedures and requirements applying to safety belts for vehicles of categories T and C referred to in Article 18(2)(j) of Regulation (EU) No 167/2013 shall be conducted and verified in accordance with Annex XIX to this Regulation.

Article 23

Requirements applying to the protection against penetrating objects

The test procedures and requirements applying to the protection against penetrating objects for vehicles of categories T and C referred to in Article 18(2)(k) of Regulation (EU) No 167/2013 shall be conducted and verified in accordance with Annex XX to this Regulation.

Article 24

Requirements applying to exhaust systems

The test procedures and requirements applying to exhaust systems for vehicles of categories T and C referred to in Article 18(2)(l) of Regulation (EU) No 167/2013 shall be conducted and verified in accordance with Annex XXI to this Regulation.

Article 25

Requirements applying to the operator’s manual

The requirements applying to the operator’s manual, including aspects relating to the protection against hazardous substances and operation and maintenance of the vehicle, for vehicles of categories T, C, R and S referred to in points (l), (n) and (q) of Article 18(2) of Regulation (EU) No 167/2013 shall be laid down in Annex XXII to this Regulation.

Article 26

Requirements applying to control devices, including safety and reliability of control systems and emergency and automatic stop devices

The test procedures and requirements applying to control devices, including safety and reliability of control systems and emergency and automatic stop devices for vehicles of categories T and C referred to in Article 18(2)(o) of Regulation (EU) No 167/2013 shall be conducted and verified in accordance with Annex XXIII to this Regulation.

Article 27

Requirements applying to the protection against other mechanical hazards

The test procedures and requirements applying to the protection against mechanical hazards, including aspects relating to the protection against rough surfaces, sharp edges and angles, rupture of pipes carrying fluids and uncontrolled movement of the vehicle, other than those mentioned in Articles 9 to 14, 19 and 23 for vehicles of categories T, C, R and S referred to in Article 18(2)(p) of Regulation (EU) No 167/2013 shall be conducted and verified in accordance with Annex XXIV to this Regulation.

Article 28

Requirements applying to guards and protective devices

The test procedures and requirements applying to guards and protective devices for vehicles of categories T, C, R and S referred to in Article 18(2)(r) of Regulation (EU) No 167/2013 shall be conducted and verified in accordance with Annex XXV to this Regulation.

Article 29

Requirements applying to information, warnings and markings

The test procedures and requirements applying to information, warnings and markings, including aspects relating to the warning signals with regard to braking and the operation and maintenance of the vehicle, for vehicles of categories T, C, R and S referred to in Article 18(2)(s) of Regulation (EU) No 167/2013 shall be conducted and verified in accordance with Annex XXVI to this Regulation.

Article 30

Requirements applying to materials and products

The test procedures and requirements applying to materials and products for vehicles of categories T and C referred to in Article 18(2)(t) of Regulation (EU) No 167/2013 shall be conducted and verified in accordance with Annex XXVII to this Regulation.

Article 31

Requirements applying to batteries

The test procedures and requirements applying to batteries for vehicles of categories T and C referred to in Article 18(2)(u) of Regulation (EU) No 167/2013 shall be conducted and verified in accordance with Annex XXVIII to this Regulation.

Article 32

Requirements applying to protection against hazardous substances

The test procedures and requirements applying to protection against hazardous substances for vehicles of categories T and C referred to in Article 18(2)(l) of Regulation (EU) No 167/2013 shall be conducted and verified in accordance with Annex XXIX to this Regulation.

CHAPTER III

REQUIREMENTS RELATING TO TECHNICAL SERVICES

Article 33

Performance standards and assessment of technical services

Technical services have to comply with the performance standards and the procedure for their assessment referred to in Article 61 of Regulation (EU) No 167/2013, which shall be verified in accordance with Annex XXX to this Regulation.

Article 34

Permissibility of self-testing

Self-testing by in-house technical services referred to in Article 60(1) of Regulation (EU) No 167/2013 may only be conducted where permitted in Annex III to this Regulation.

CHAPTER IV

NATIONAL TYPE-APPROVAL OF VEHICLES, SYSTEMS, COMPONENTS OR SEPARATE TECHNICAL UNITS

Article 35

National type-approval of vehicles, systems, components or separate technical units

National authorities shall not refuse to grant national type-approval to a type of vehicle, system, component or separate technical unit on grounds relating to the construction requirements where the vehicle, system, component or separate technical unit complies with the requirements set out in this Regulation.

CHAPTER V

FINAL PROVISIONS

Article 36

Amendments to Annex I to Regulation (EU) No 167/2013

Annex I to Regulation (EU) No 167/2013 is amended as follows:

Article 37

Entry into force and application

This Regulation shall enter into force on the twentieth day following that of its publication in the Official Journal of the European Union.

It shall apply from 1 January 2016.

This Regulation shall be binding in its entirety and directly applicable in all Member States.

Done at Brussels, 19 September 2014.

For the Commission

The President

José Manuel BARROSO

• (1) 

  OJ L 60, 2.3.2013, p. 1.

• (2) 

  Council Decision 97/836/EC of 27 November 1997 with a view to accession by the European Community to the Agreement of the United Nations Economic Commission for Europe concerning the adoption of uniform technical prescriptions for wheeled vehicles, equipment and parts which can be fitted to and/or be used on wheeled vehicles and the conditions for reciprocal recognition of approvals granted on the basis of these prescriptions (Revised 1958 Agreement) (OJ L 346, 17.12.1997, p. 78).

• (3) 

  Regulation (EC) No 595/2009 of the European Parliament and of the Council of 18 June 2009 on type-approval of motor vehicles and engines with respect to emissions from heavy duty vehicles (Euro VI) and on access to vehicle repair and maintenance information and amending Regulation (EC) No 715/2007 and Directive 2007/46/EC and repealing Directives 80/1269/EEC, 2005/55/EC and 2005/78/EC (OJ L 188, 18.7.2009, p. 1).

• (4) 

  Commission Regulation (EU) No 582/2011 of 25 May 2011 implementing and amending Regulation (EC) No 595/2009 of the European Parliament and of the Council with respect to emissions from heavy duty vehicles (Euro VI) and amending Annexes I and III to Directive 2007/46/EC of the European Parliament and of the Council (OJ L 167, 25.6.2011, p. 1).

• (5) 

  Council Directive 80/720/EEC of 24 June 1980 on the approximation of the laws of the Member States relating to the operating space, access to the driving position and the doors and windows of wheeled agricultural or forestry tractors (OJ L 194, 28.7.1980, p. 1).

• (6) 

  Directive 2006/42/EC of the European Parliament and of the Council of 17 May 2006 on machinery, and amending Directive 95/16/EC (OJ L 157, 9.6.2006, p. 24).

• (7) 

  Directive 2003/37/EC of the European Parliament and of the Council of 26 May 2003 on type-approval of agricultural or forestry tractors, their trailers and interchangeable towed machinery, together with their systems, components and separate technical units and repealing Directive 74/150/EEC (OJ L 171, 9.7.2003, p. 1).

SUMMARY

ANNEX I

Application of UNECE regulations

Explanatory note:

The fact that a component is included in this list does not make its installation mandatory. For certain components, however, mandatory installation requirements are laid down in other Annexes to this Regulation.

ANNEX II

Recognition of test reports issued on the basis of OECD Codes for the purposes of EU type-approval

ANNEX III

Arrangements with regard to type-approval procedures, including the requirements relating to virtual testing

• 1. 

  Type-approval process

When receiving an application for vehicle type-approval, the approval authority shall:

• 2. 

  Combination of technical specifications

The number of vehicles to be submitted shall be sufficient to permit the proper check of the various combinations to be type-approved according to the following criteria:

• 3. 

  Specific provisions

Where no approval certificates or test reports in respect of the subjects covered by Regulation (EU) No 167/2013 or the delegated and implementing acts adopted pursuant to that Regulation are available, the approval authority shall:

• 4. 

  Procedures to be followed during multi-stage EU type-approval

4.1.   General

4.2.   Procedures

The approval authority shall:

4.3.   The number of vehicles to be inspected for the purposes of point 4.2.4 shall be sufficient to permit the proper control of the various combinations to be EU type-approved according to the state of completion of the vehicle and the criteria set-out in point 2.

• 5. 

  Conditions under which virtual testing has to be performed and requirements which can be subject to virtual testing

5.1.   Objectives and scope

Point 5 lays down appropriate provisions concerning virtual testing in accordance with Article 27(6) of Regulation (EU) No 167/2013. It shall not apply to the second subparagraph of Article 27(3) of that Regulation.

5.2.   List of requirements which may be subject to virtual testing

Table 1

List of requirements which may be subject to virtual testing

• 6. 

  Conditions under which virtual testing has to be performed

6.1.   Virtual test pattern

The following scheme shall be used as a basic structure for describing and conducting virtual testing:

6.2.   Fundamentals of computer simulation and calculation

6.2.1.   Mathematical model

The mathematical model shall be supplied by the manufacturer. It shall reflect the complexity of the structure of the vehicle, system and components to be tested in relation to the requirements. The same provisions shall apply mutatis mutandis for testing components or technical units independently from the vehicle.

6.2.2.   Validation process of the mathematical model

The mathematical model shall be validated in comparison with the actual test conditions. A physical test shall be conducted for the purposes of comparing the results obtained when using the mathematical model with the results of a physical test. Comparability of the test results shall be proven. A validation report shall be drafted by the manufacturer or by the technical service and submitted to the approval authority. Any change made to the mathematical model or to the software likely to invalidate the validation report shall be brought to the attention of the approval authority, which may require that a new validation process is conducted. The flow chart of the validation process is shown in Figure 1 of point 7.

6.2.3.   Documentation

The data and auxiliary tools used for the simulation and calculation shall be made available by the manufacturer and be documented in a suitable way.

6.2.4.   Tools and support

At the request of the technical service, the manufacturer shall supply or provide access to the necessary tools, including appropriate software.

6.2.5.   In addition, the manufacturer shall provide appropriate support to the technical service.

6.2.6.   Providing access and support to a technical service does not detract from any obligation of the technical service regarding the skills of its personnel, the payment of licence rights and respect of confidentiality.

• 7. 

  Validation process virtual testing

Figure 1

Virtual testing validation process flow chart

ANNEX IV

Arrangements with regard to conformity of production

• 1. 

  Definitions

For the purposes of this Annex the following definitions shall apply:

• 2. 

  Purpose

• 3. 

  Initial assessment

• 4. 

  Product conformity arrangements

• 5. 

  Continued verification arrangements

ANNEX V

Requirements with regard to access to repair and maintenance information

LIST OF APPENDICES

• 1. 

  Definition

For the purposes of this Annex the following definition shall apply: ‘access to Vehicle OBD and Vehicle Repair and Maintenance Information’ means the availability of all OBD and repair and maintenance information required for the inspection, diagnosis, servicing or repair of the vehicle.

• 2. 

  Compliance with access to vehicle OBD and vehicle repair and maintenance information requirements in the type-approval procedure

• 3. 

  Fees for access

In addition to time-based access under Article 55 of Regulation (EU) No 167/2013, manufacturers may offer transaction-based access for which fees are charged per transaction and not based on the time for which access is granted. Where manufacturers offer both time-based and transaction-based access systems, independent repairers shall choose a preferred access system, either time-based or transaction based.

• 4. 

  Service parts, diagnostic tools and test equipment

• 5. 

  Multi-stage type-approval

• 6. 

  Small volume manufacturers

• 7. 

  Compliance with the obligations regarding access to vehicle OBD and vehicle repair and maintenance information

• 8. 

  Information requirements for granting access to independent operators to non-secure areas

• 9. 

  Information requirements for granting access to independent operators to secure areas

Appendix 1

Access to vehicle OBD and vehicle repair and maintenance information

• 1. 

  Introduction

• 2. 

  Requirements

Appendix 2

Information to enable the development of generic diagnostic tools

• 1. 

  Information required for the manufacture of diagnostic tools

In order to facilitate the provision of generic diagnostic tools for multi-make repairers, vehicle manufacturers shall make available the information referred to in points 1.1, 1.2 and 1.3 through their repair information websites. That information shall include all diagnostic tool functions and all the links to repair information and troubleshooting instructions. The access to the information may be subject to the payment of a reasonable fee.

1.1.   Communication protocol information

The following information shall be required indexed against vehicle make, model and variant, or other workable definition such as VIN or vehicle and systems identification:

1.2.   Test and diagnosis of OBD monitored components

The following information shall be required:

1.3.   Data required to perform the repair

The following information shall be required:

ANNEX VI

Requirements applying to roll-over protection structures (dynamic testing)

• A. 

  GENERAL PROVISION

• B. 

  REQUIREMENTS APPLYING TO ROLL-OVER PROTECTION STRUCTURES (DYNAMIC TESTING) (1)

• 1. 

  Definitions

1.1.   [Not applicable]

1.2.   Rolling Over Protective Structure (ROPS)

Roll-over protective structure (protective cab or frame), hereinafter called ‘protective structure’, means the structure on a tractor the essential purpose of which is to avoid or limit risks to the driver resulting from roll-over of the tractor during normal use.

The roll-over protective structure is characterized by the provision of space for a clearance zone large enough to protect the driver when seated either inside the envelope of the structure or within a space bounded by a series of straight lines from the outer edges of the structure to any part of the tractor that might come into contact with flat ground and that is capable of supporting the tractor in that position if the tractor overturns.

1.3.   Track

1.3.1.   Preliminary definition: median plane of the wheel

The median plane of the wheel is equidistant from the two planes containing the periphery of the rims at their outer edges.

1.3.2.   Definition of track

The vertical plane through the wheel axis intersects its median plane along a straight line which meets the supporting surface at one point. If A and B are the two points thus defined for the wheels on the same axle of the tractor, then the track width is the distance between points A and B. The track may be thus defined for both front and rear wheels. Where there are twin wheels, the track is the distance between two planes each being the median plane of the pairs of wheels.

For track-laying tractors, the track is the distance between the median planes of the tracks.

1.3.3.   Additional definition: median plane of the tractor

Take the extreme positions of points A and B for the tractor rear axle, which gives the maximum possible value for the track. The vertical plane at right angles to the line AB at its centre point is the median plane of the tractor.

1.4.   Wheelbase

The distance between the vertical planes passing through the two lines AB as defined above, one for the front wheels and one for the rear-wheels.

1.5.   Determination of seat index point; Seat location and adjustment for test

1.5.1.   Seat Index Point (SIP) (2)

The seat index point shall be determined in accordance with ISO 5353:1995.

1.5.2.   Seat location and adjustment for test

1.6.   Clearance zone

1.6.1.   Reference plane

The clearance zone is illustrated in Figures 3.8 to 3.10 and Table 3.3. The zone is defined in relation to the reference plane and the Seat Index Point. The reference plane is a vertical plane, generally longitudinal to the tractor and passing through the Seat Index Point and the centre of the steering wheel. Normally the reference plane coincides with the longitudinal median plane of the tractor. This reference plane shall be assumed to move horizontally with the seat and steering wheel during loading but to remain perpendicular to the tractor or the floor of the roll-over protective structure. The clearance zone shall be defined on the basis of sub clauses 1.6.2 and 1.6.3.

1.6.2.   Determination of clearance zone for tractors with a non-reversible seat

The clearance zone for tractors with a non-reversible seat is defined in 1.6.2.1 to 1.6.2.10 below and is bounded by the following planes, the tractor being on a horizontal surface, the seat, where adjustable, adjusted to its rear uppermost position (2), and the steering wheel, where adjustable, adjusted to the mid position for seated driving:

1.6.3.   Determination of clearance zone for tractors with a reversible driver’s position

For tractors with a reversible driver’s position (reversible seat and steering wheel), the clearance zone is the envelope of the two clearance zones defined by the two different positions of the steering wheel and the seat.

1.6.4.   Optional seats

1.7.   Unballasted mass

The mass of the tractor without ballasting devices and, in the case of tractors with pneumatic tyres, without liquid ballast in the tyres. The tractor shall be in running order with tanks, circuits and radiator full, protective structure with cladding and any track equipment or additional front wheel drive components required for normal use. The operator is not included.

1.8.   Permissible measurement tolerances

1.9.   Symbols

• 2. 

  Field of application

2.1.   This Annex is applicable to tractors having at least two axles for pneumatic tyred wheels with or without track attachments and with an unballasted tractor mass greater than 600 kg but generally less than 6 000 kg.

2.2.   The minimum track width of the rear-wheels should generally be greater than 1 150 mm. It is recognised that there may be designs of tractors, for example, lawn mowers, narrow vineyard tractors, low profile tractors used in buildings with limited overhead clearance or in orchards, high-clearance tractors and special forestry machines, such as forwarders and skidders, for which this Annex is not applicable.

• 3. 

  Rules and directions

3.1.   General regulations

3.1.1.   The protective structure may be manufactured either by the tractor manufacturer or by an independent firm. In either case a test is only valid for the model of tractor on which it is carried out. The protective structure must be retested for each model of tractor to which it is to be fitted. However, testing stations may certify that the strength tests are also valid for tractor models derived from the original model by modifications to the engine, transmission and steering and front suspension (see below 3.6: Extension to other tractor models). On the other hand, more than one protective structure may be tested for any one model of tractor.

3.1.2.   The protective structure submitted for dynamic test must be supplied attached in the normal manner to the tractor model in connection with which it is being tested. The tractor submitted shall be complete and in running order.

3.1.3.   Where a ‘tandem’ tractor is concerned, the mass of the standard version of that part to which the protective structure is fitted is to be used.

3.1.4.   A protective structure may be designed solely to protect the driver in the event of the tractor overturning. Onto this structure it may be possible to fit weather protection for the driver, of a more or less temporary nature. The driver will usually remove this in warm weather. There are protective structures however, in which the cladding is permanent and warm weather ventilation provided by windows or flaps. As the cladding may add to the strength of the structure and if removable may well be absent when an accident occurs, all parts that can be so taken away by the driver will be removed for the purpose of the test. Doors, roof hatch and windows that can be opened shall be either removed or fixed in the open position for the test, so that they do not add to the strength of the protective structure. It shall be noted whether, in this position, they would create a hazard for the driver in the event of overturning.

Throughout the remainder of these rules, reference will only be made to testing the protective structure. It must be understood that this includes cladding not of a temporary nature.

A description of any temporary cladding supplied is to be included in the specifications. All glass or similar brittle material shall be removed prior to the test. Tractor and protective structure components which might sustain needless damage during the test and which do not affect the strength of the protective structure or its dimensions may be removed prior to the test if the manufacturer wishes. No repairs or adjustment may be carried out during the test.

3.1.5.   Any component of the tractor contributing to the strength of the protective structure such as mud-guards, which has been reinforced by the manufacturer, should be described and its measurements given in the test report.

3.2.   Apparatus and test conditions

3.2.1.   The structure shall be struck by a block acting as a pendulum and submit to a front and a rear crushing test.

3.2.2.   The mass of the pendulum bloc (Figure 3.1) shall be 2 000 kg. Its impact face shall have dimensions 680 × 680 mm ± 20. It shall be made in such a way that the position of its centre of gravity is constant (for example with iron bars bound in concrete). It shall be suspended from a pivot point about 6 m above the floor in such a way that the height of the pendulum may be conveniently and safely adjusted.

3.2.3.   For tractors with less than 50 % of their mass on the front wheels, the first blow shall be at the rear of the structure. This shall be followed by a crushing test also at the rear of the structure. The second blow shall be at the front and the third at the side. Finally, there shall be a second crushing test at the front.

For tractors with 50 % or more of their mass on the front wheels, the first blow shall be at the front and the second blow at the side. This shall be followed by the two crushing tests, firstly at the rear and secondly at the front.

3.2.4.   For tractors with a reversible driver’s position (reversible seat and steering wheel), the first blow shall be longitudinal at the heavier end (with more than 50 % of the mass of the tractor). This shall be followed by a crushing test on the same end. The second blow shall be at the other end, and the third at the side. Finally, there shall be a second crushing test at the lighter end.

3.2.5.   A track width setting for the rear-wheels shall be chosen such that the structure is in no way supported by the tyres during the test. This provision may be disregarded if such support is given when the wheels are in their widest alternative track setting.

3.2.6.   The side of the tractor from which the side blow is struck shall be that which, in the opinion of the testing station, is likely to give the greatest distortion. The rear blow shall be on the corner opposite the side blow and the front blow on the corner nearer the side blow. The rear blow shall be administered at two-thirds the distance from the median plane of the tractor to the vertical plane touching the outside extremity of the structure. However, if a curve in the back of the structure starts at less than two-thirds of the distance from the centre, the blow shall be struck at the beginning of the curve, i.e. at the point where this curve is tangential to a line at right angles to the median plane of the tractor.

3.2.7.   If, during the test, any lashings, props or blocks move or break, the test must be repeated.

3.3.   Impact tests

3.3.1.   Impact at the rear (Figures 3.2.a and 3.2.b)

3.3.1.1.   The rear impact is not required on tractors having 50 % or more of their mass (as defined above) on the front wheels.

3.3.1.2.   The tractor shall be placed in relation to the pendulum so that this will strike the structure when the striking face and the supporting chains are at an angle of 20° to the vertical unless the structure at the point of contact has, during deflection, a greater angle with the vertical. In this case the striking face shall be adjusted parallel to the side of the structure at the point of contact at the moment of maximum deflection by an additional support, the supporting chains remaining at an angle of 20° to the vertical. The point of impact shall be that part of the structure likely to hit the ground first in a rearward overturning accident, normally the upper edge. The height of the pendulum will be so adjusted that it has no tendency to turn about the point of contact.

3.3.1.3.   The tractor will be lashed down. The points of attachment of the lashings shall be approximately 2 m behind the rear axle and 1,5 m in front of the front axle. There shall be two lashings on each axle, one on each side of the median plane of the tractor. The lashings shall be steel cable of 12,5 to 15 mm diameter, tensile strength 1 100-1 260 MPa. The tyres of the tractor shall be inflated, and the lashings tightened to give tyre pressures and deflections, as shown in the Table 3.1, below.

After the lashings have been tightened a wood beam 150 × 150 mm shall be clamped in front of the rear-wheels, driven tight against them.

3.3.1.4.   The pendulum shall be pulled back so that the height H of its centre of gravity above that at the point of impact is given by one of the following formulae at the option of the manufacturer:

or

3.3.1.5.   The pendulum shall be released and allowed to crash against the structure. The quick release mechanism must be so positioned that it does not tilt the weight in relation to the chains supporting it at the moment of release.

Table 3.1

Tyre Pressures

3.3.2.   Impact at the front (Figures 3.3.a and 3.3.b)

3.3.2.1.   This shall be carried out in the same way as the impact at the rear. The lashings shall be the same but the wooden beam shall be behind the rear-wheels. The height of fall of the centre of gravity of the pendulum shall be given by the following formula:

3.3.2.2.   The point of impact shall be that part of the structure that would hit the ground first when turning over sideways while travelling forward, normally the top of the front corner.

3.3.3.   Impact at the side (Figure 3.4)

3.3.3.1.   The tractor shall be placed in relation to the pendulum so that this will strike the structure when the striking face and the supporting chains are vertical unless the structure at the point of contact is, during deflection, other than vertical. In this case the striking face shall be adjusted so that it is approximately parallel to the structure at the point of contact at the moment of maximum deflection. This adjustment shall be made by an additional support, the supporting chains remaining vertical at the moment of impact. The point of impact shall be that part of the structure likely to hit the ground first in a sideways overturning accident, normally the upper edge.

3.3.3.2.   Unless it is certain that any other part of this edge would hit the ground first, the point of impact shall be in the plane at right angles to the median plane of the tractor and passing 60 mm in front of the seat index point, the seat being at its mid-point of longitudinal adjustment. The height of the pendulum will be so adjusted that it has no tendency to turn about the point of contact.

3.3.3.3.   For tractors with a reversible driver’s position, the point of impact shall be in the plane at right angles to the median plane of the tractor and at the mid-point between the two seat index points.

3.3.3.4.   The rear-wheel of the tractor on the side to be struck shall be lashed down. The tension in the lashings shall be determined as for the impact at the rear. After lashing, a beam 150 × 150 mm shall be clamped against the side of the rear-wheel opposite the blow, and driven hard against the tyre. A beam shall be placed as a prop against this wheel and secured on the floor so that it is held tight against the wheel during impact. The length of this beam shall be chosen so that when in position against the wheel it makes an angle of 25 to 40° with the horizontal. Furthermore its length shall be 20 to 25 times its thickness and its width 2 to 3 times its thickness.

3.3.3.5.   The pendulum shall be pulled back as in the previous tests so that the height H of its centre of gravity above that at the moment of impact is determined by the following formula:

3.3.3.6.   During the side impact test the difference between the maximum momentary deflection and the permanent deflection at a height of (810 + av) mm above the seat index point shall be recorded. This may be done with a device on which a moving friction collar shall be fitted on a horizontal rod. One end of the rod shall be attached to the top member of the structure and the other will pass through a hole in a vertical bar attached to tractor chassis. The collar will be positioned against the vertical bar attached to tractor chassis before the blow and its distance from it after the blow will give the difference between the maximum momentary deflection and the permanent deflection.

3.4.   Crushing tests

It may be necessary to hold down the front of the tractor when carrying out the test at the rear. Blocks will be placed under the axles so that the tyres do not bear crushing force. The cross beam used shall have a width of approximately 250 mm and shall be connected to the load applying mechanism by universal joints (Figure 3.5).

3.4.1.   Crushing at the rear (Figures 3.6.a and 3.6.b)

3.4.1.1.   The crushing beam shall be positioned across the rear uppermost structural members so that the resultant of the crushing forces is located in the vertical reference plane of the tractor. The crushing force (F) shall be applied where:

F = 20 M

This force shall be maintained for 5 seconds after cessation of any visually detectable movement of the protective structure.

3.4.1.2.   Where the rear part of the protective structure roof will not sustain the full crushing force (Figures 3.7.a and 3.7.b), the force shall be applied until the roof is deflected to coincide with the plane joining the upper part of the protective structure with that part of the rear of the tractor capable of supporting the tractor when overturned.

The force shall then be removed and the crushing beam repositioned over that part of the protective structure that would support the tractor when completely overturned. The crushing force F shall be applied.

3.4.2.   Crushing at the front (Figures 3.6.a and 3.6.b)

3.4.2.1.   The crushing beam shall be positioned across the front uppermost structural members so that the resultant of the crushing forces is located in the vertical reference plane of the tractor. The crushing force (F) shall be applied where:

F = 20 M

This force shall be maintained for 5 seconds after cessation of any visually detectable movement of the protective structure.

3.4.2.2.   When the front part of the roof of the protective structure will not sustain the full crushing force (Figures 3.7.a and 3.7.b), the force shall be applied until the roof is deflected to coincide with the plane joining the upper part of the protective structure with that part of the front of the tractor capable of supporting the tractor when overturned.

The force shall then be removed and the crushing beam repositioned over that part of the protective structure that would support the tractor when completely overturned. The crushing force F shall then be applied.

3.5.   Conditions for acceptance

3.5.1.   The structure and tractor shall be visually examined for cracks and tears after each part of the test. For the structure to pass the test the following conditions shall be complied with:

3.5.2.   After the final crushing test, the permanent deformation of the protective structure shall be recorded. For this purpose, before the start of the test, the position of the main members in relation to the seat index point must be recorded. Then any movement of the members struck in the tests and any change of the height of the front and back members of the roof shall be recorded.

3.6.   Extension to other tractor models

3.6.1.   [Not applicable]

3.6.2.   Technical extension

When technical modifications occur on the tractor, the protective structure or the method of attachment of the protective structure to the tractor, the testing station that has carried out the original test can issue a ‘technical extension report’ in the following cases:

3.6.2.1.   Extension of the structural test results to other models of tractors

The impact and crushing tests need not be carried out on each model of tractor, provided that the protective structure and tractor comply with the conditions referred to hereunder 3.6.2.1.1 to 3.6.2.1.5.

3.6.2.2.   Extension of the structural test results to modified models of the protective structure

This procedure has to be followed when the provisions of paragraph 3.6.2.1 are not fulfilled, it may not be used when the method of attachment of the protective structure to the tractor does not remain of the same principle (e.g. rubber supports replaced by a suspension device):

3.7.   [Not applicable]

3.8.   Cold weather performance of protective structures

3.8.1.   If the protective structure is claimed to have properties resistant to cold weather embrittlement, the manufacturer shall give details that shall be included in the report.

3.8.2.   The following requirements and procedures are intended to provide strength and resistance to brittle fracture at reduced temperatures. It is suggested that the following minimum material requirements shall be met in judging the protective structure’s suitability at reduced operating temperatures in those countries requiring this additional operating protection.

Table 3.2

Minimum Charpy V-notch impact energies

3.8.2.1.   Bolts and nuts used to attach the protective structure to the tractor and used to connect structural parts of the protective structure shall exhibit suitable controlled reduced temperature toughness properties.

3.8.2.2.   All welding electrodes used in the fabrication of structural members and mounts shall be compatible with the protective structure material as given in 3.8.2.3 below.

3.8.2.3.   Steel materials for structural members of the protective structure shall be of controlled toughness material exhibiting minimum Charpy V-Notch impact energy requirements as shown in Table 3.2. Steel grade and quality shall be specified in accordance with ISO 630:1995; Amd1:2003.

Steel with an as-rolled thickness less than 2,5 mm and with a carbon content less than 0,2 % is considered to meet this requirement. Structural members of the protective structure made from materials other than steel shall have equivalent low temperature impact resistance.

3.8.2.4.   When testing the Charpy V-Notch impact energy requirements, the specimen size shall be no less than the largest of the sizes stated in Table 3.2 that the material will permit.

3.8.2.5.   The Charpy V-Notch tests shall be made in accordance with the procedure in ASTM A 370-1979, except for specimen sizes that shall be in accordance with the dimensions given in Table 3.2.

3.8.2.6.   Alternatives to this procedure are the use of killed or semi-killed steel for which an adequate specification shall be provided. Steel grade and quality shall be specified in accordance with ISO 630:1995; Amd1:2003.

3.8.2.7.   Specimens are to be longitudinal and taken from flat stock, tubular or structural sections before forming or welding for use in the protective structure. Specimens from tubular or structural sections are to be taken from the middle of the side of greatest dimension and shall not include welds.

3.9.   [Not applicable]

Figure 3.1

Pendulum block and its suspending chains or wire ropes

(Dimensions in mm)

Figure 3.2

Method of impact from rear

Figure 3.2.a

Protective cab

Figure 3.2.b

Rear roll bar frame

Figure 3.3

Method of impact from front

Figure 3.3.a

Protective cab

Figure 3.3.b

Rear roll bar frame

Figure 3.4

Method of impact from side

Figure 3.5

Example of an arrangement for crushing tests

Figure 3.6

Position of beam for front and rear crushing tests

Figure 3.6.a

Protective cab

Figure 3.6.b

Rear roll bar frame

Figure 3.7

Position of beam for front crushing test when full crushing force not sustained in front

Figure 3.7.a

Protective cab

Figure 3.7.b

Rear roll bar frame

Table 3.3

Dimensions of the clearance zone

Figure 3.8

Clearance zone

Note:

for dimensions, see Table 3.3 above;

Figure 3.9

Clearance zone

Figure 3.10

Clearance zone for tractor with reversible seat and steering wheel

Figure 3.10.a

Protective cab

Figure 3.10.b

Rear roll bar frame

Figure 3.11

Example of apparatus for measuring elastic deflection

Explanatory notes to Annex VI

• (1) 

  Unless otherwise stated, the text of the requirements and the numbering set out in point B are identical with the text and numbering of the OECD standard code for the official testing of protective structures on agricultural and forestry tractors (dynamic test), OECD Code 3, Edition 2015 of July 2014.

• (2) 

  Users are reminded that the seat index point is determined according to ISO 5353 and is a fixed point with respect to the tractor that does not move as the seat is adjusted away from the mid-position. For purposes of determining the clearance zone, the seat shall be placed in the rear and uppermost position.

• (3) 

  No water ballast is to be used.

• (4) 

  Indicates preferred size. Specimen size shall be no less than largest preferred size that the material permits.

• (5) 

  The energy requirement at – 20 °C is 2,5 times the value specified for – 30 °C. Other factors affect impact energy strength, i.e. direction of rolling, yield strength, grain orientation and welding. These factors shall be considered when selecting and using steel.

ANNEX VII

Requirements applying to roll-over protection structures (track-laying tractors)

• A. 

  GENERAL PROVISION

• B. 

  REQUIREMENTS APPLYING TO ROLL-OVER PROTECTION STRUCTURES (TRACK-LAYING TRACTORS)(1)

• 1. 

  Definitions

1.1.   [Not applicable]

1.2.   Rolling Over Protective Structure (ROPS)

Roll-over protective structure (protective cab or frame), hereinafter called ‘protective structure’, means the structure on a tractor the essential purpose of which is to avoid or limit risks to the driver resulting from roll-over of the tractor during normal use.

The roll-over protective structure is characterised by the provision of space for a clearance zone large enough to protect the driver when seated either inside the envelope of the structure or within a space bounded by a series of straight lines from the outer edges of the structure to any part of the tractor that might come into contact with flat ground and that is capable of supporting the tractor in that position if the tractor overturns.

1.3.   Track

1.3.1.   Preliminary definition: median plane of the track

The median plane of the track is equidistant from the two planes containing its periphery at their outer edges.

1.3.2.   Definition of track width

Track width is the distance between the median planes of the tracks

1.3.3.   Additional definition: median plane of the tractor

The vertical plane at right angles to the axle at its centre point is the median plane of the tractor.

1.4.   Protective structure

System of structural members arranged on a tractor in such a way as to accomplish its primary purpose of reducing the likelihood of an operator being crushed should his tractor roll-over. Structural members include any sub-frame, bracket, mounting, socket, bolt, pin, suspension or flexible shock absorber used to secure the system to the tractor frame but exclude mounting provisions which are integral with the tractor frame.

1.5.   Tractor frame

The main chassis or main load-bearing member(s) of the tractor which extend(s) over a major part of the tractor and upon which the protective structure is directly mounted.

1.6.   Protective structure-tractor frame assembly

System consisting of the protective structure attached to the tractor frame.

1.7.   Bedplate

A substantially rigid part of the test structure to which the tractor frame is attached for the purpose of the test.

1.8.   Seat index point (SIP)

1.8.1.   The seat index point (SIP) is located in the central longitudinal plane of the apparatus for determination when installed in the operator seat. The SIP is fixed with respect to the tractor and does not move with the seat through its range of adjustment and/or oscillation.

1.8.2.   When determining the SIP, the seat shall be adjusted with all fore, aft, vertical and angular seat adjustments placed in their centre position. The suspension systems shall be set so that the seat is at the mid-point of its oscillation range with the weighted apparatus for determination of SIP in place.

1.8.3.   The SIP must be established by means of the apparatus illustrated in Figure 8.1. The apparatus is placed on the seat. A 20 kg mass is added 40 mm in front of the SIP mark on the horizontal section of the apparatus. A horizontal force of about 100 N shall then be applied to the apparatus at the SIP (see Fo in Figure 8.1). Finally, a further 39 kg mass shall be placed 40 mm in front of the SIP mark on the horizontal section of the apparatus.

1.9.   Deflection-limiting volume (DLV)

That volume, related to the operator, which serves to set limits and deflections permissible when performing laboratory evaluations of the protective structure (Figure 8.2). It is an orthogonal approximation of the dimensions of a large, seated operator.

1.10.   Vertical reference plane

A vertical plane, generally longitudinal to the tractor and passing through the seat index point and the centre of the steering wheel or of the control hand levers. Normally, the vertical reference plane coincides with the median plane of the tractor.

1.11.   Lateral simulated ground plane

Surface on which a tractor, after rolling over, is assumed to come to a standstill with the tractor lying on its side. The simulated ground plane is determined as follows (see 3.5.1.2):

The simulated ground plane shall be established on an unloaded protective structure and shall move with the member to which the load is applied.

1.12.   Vertical simulated ground plane

For a machine coming to rest in an upside-down position, the plane is defined by the top cross-member of the protective structure and that front (rear) part of the tractor likely to come in contact with flat ground at the same time as the protective structure and capable of supporting the upside-down tractor. The vertical simulated ground plane moves with the deformed protective structure.

1.13.   Unballasted mass

The mass of the tractor without ballasting devices. The tractor shall be in running order with tanks, circuits and radiator full, protective structure with cladding and any track equipment or additional front wheel drive components required for normal use. The operator is not included.

1.14.   Permissible measurement tolerances

1.15.   Symbols

• 2. 

  Field of application

This Annex is applicable to tractors, propelled and steered by endless tracks, having at least two axles with track attachments, and with following features:

• 3. 

  Rules and directions

3.1.   General regulations

3.1.1.   The protective structure may be manufactured either by the tractor manufacturer or by an independent firm. In either case a test is only valid for the model of tractor on which it is carried out. The protective structure must be retested for each model of tractor to which it is to be fitted. However, testing stations may certify that the strength tests are also valid for tractor models derived from the original model by modifications to the engine, transmission and steering and front suspension (see below 3.6: Extension to other tractor models). On the other hand, more than one protective structure may be tested for any one model of tractor.

3.1.2.   The protective structure submitted for test must be supplied attached in the normal manner to the tractor or tractor chassis on which it is used. The tractor chassis shall be complete including attaching brackets and other parts of the tractor that may be affected by loads imposed on the protective structure.

3.1.3.   A protective structure may be designed solely to protect the driver in the event of the tractor overturning. Onto this structure it may be possible to fit weather protective for the driver, of a more or less temporary nature. This will usually be removed by the driver in warm weather. There are protective structures however, in which the cladding is permanent and warm weather ventilation provided by windows or flaps. As the cladding may add to the strength of the structure and if removable may well be absent when an accident occurs, all parts that can be so taken away by the driver will be removed for the purpose of the test. Doors, roof hatch and windows which can be opened shall be either removed or fixed in the open position for the test, so that they do not add to the strength of the protective structure. It shall be noted whether, in this position, they would create a hazard for the driver in the event of overturning.

Throughout the remainder of these rules, reference will only be made to testing the protective structure. It must be understood that this includes cladding not of a temporary nature.

A description of any temporary cladding supplied is to be included in the specifications. All glass or similar brittle material shall be removed prior to the test. Tractor and protective structure components which might sustain needless damage during the test and which do not affect the strength of the protective structure or its dimensions may be removed prior to the test if the manufacturer wishes. No repairs or adjustment may be carried out during the test.

3.1.4.   Any component of the tractor contributing to the strength of the protective structure such as mud-guards, which has been reinforced by the manufacturer, should be described and its measurements given in the test report.

3.2.   Apparatus

3.2.1.   Deflection-limiting volume

The DLV and its location shall be in accordance with ISO 3164:1995 (see Figure 8.3). The DLV shall be fixed firmly to the same part of the machine to which the operator's seat is secured, and shall remain there during the entire formal test period.

For track-laying tractors with an unballasted mass of less than 5 000 kg, fitted with a two-post front mounted protective structure, the DLV corresponds to Figures 8.4 and 8.5.

3.2.2.   Zone of clearance and safeguard plane

The zone of clearance, as defined in Annex VIII (Definitions Chapter, Section 1.6), must remain covered by the safeguard plane, S, as shown in Figures 8.2 and 8.4. The safeguard plane is defined as an oblique plane, perpendicular to the vertical longitudinal plane of the tractor, forming a tangent at the front with the protective structure and at the back with whichever of the following hard fixtures of the tractor prevents the aforementioned plane S from entering the zone of clearance, via:

3.2.3.   Rear hard fixture test

If the tractor is fitted with a rigid section, a housing or other hard fixture placed behind the driver’s seat, this fixture shall be regarded as a protective point, in the event of sideways or rear overturning. This hard fixture placed behind the driver’s seat shall be capable of withstanding, without breaking or entering the zone of clearance, a downward force Fi where:

applied perpendicularly to the top of the frame in the central plane of the tractor. The initial angle of application of force shall be 40° calculated from a parallel to the ground as shown in Figure 8.4. The minimum width of this rigid section shall be 500 mm (see Figure 8.5).

In addition, it shall be sufficiently rigid and firmly attached to the rear of the tractor.

3.2.4.   Lashings

Facilities for securing the protective structure-tractor frame assembly to the bedplate, as described above, and for applying the horizontal and vertical loads shall be provided (see Figures 8.6 to 8.9).

3.2.5.   Measuring instruments

The test apparatus shall be equipped with instruments for measuring the force applied to the protective structure and the deflection (deformation) of the structure.

The percentages below are nominal ratings of the accuracy of the instrumentation and shall not be taken to indicate that compensating tests are required.

3.2.6.   Arrangements for load application

Loading arrangements for load application are shown in Figures 8.7, 8.10 to 8.13 (side loading), in Figures 8.8 and 8.9 (vertical loading) and Figure 8.14 (longitudinal loading).

3.3.   Test conditions

3.3.1.   The protective structure shall comply with production specifications and shall be fitted to the appropriate tractor model chassis in accordance with the manufacturer's declared method of attachment.

3.3.2.   The protective structure - tractor frame assembly shall be secured to the bedplate so that the members connecting the assembly and the bedplate experience minimal deflection when the protective structure is side loaded. During side loading, the protective structure - tractor frame assembly shall not receive any support from the bedplate, other than that due to the initial attachment.

3.3.3.   The protective structure shall be instrumented with the necessary equipment to obtain the required force-deflection data.

3.3.4.   All tests shall be performed on the same protective structure. No repair or straightening of any protective structure - tractor member shall be carried out during or between the side and vertical loadings.

3.3.5.   For side and longitudinal loading, connection to the bedplate shall be through the main housing or track frames (see Figures 8.6 to 8.8).

3.3.6.   For vertical loading, there is no limitation on securing or supporting the protective structure-tractor frame assembly.

3.3.7.   On completion of all the tests, permanent deflections of the protective structure shall be measured and recorded.

3.4.   Test procedure

3.4.1.   General

The test procedures shall consist of the operations described in 3.4.2, 3.4.3 and 3.4.4 in the order listed.

3.4.2.   Side loading

3.4.2.1.   The force-deflection characteristics shall be determined by side loading the top major longitudinal members of the protective structure.

For a protective structure having more than two posts, the side loading shall be applied through a load-distribution device having a length not greater than 80 per cent of the top member straight length L between the front and rear posts of the protective structure (see Figures 8.13 to 8.16). The initial loading shall be within the zone that is established by the vertical projection of two planes parallel to the front and rear planes of the DLV and located 80 mm outside of them.

3.4.2.2.   For a protective structure with an overhead shield, having a two-post system, the initial loading shall be dictated by the total longitudinal distance between major, upper protective structure members L and the vertical projection of the front and rear planes of the DLV. The force (load) point shall not be within L/3 distance from the posts.

Should the L/3 point be between the vertical projection of the DLV and the posts, the force (load) point shall be moved away from the post until it enters the vertical projection of the DLV (see Figures 8.13 to 8.16). Any load distribution plate used shall not impede or restrict the rotation of the protective structure around a vertical axis during the loading and shall not distribute the load over a distance greater than 80 per cent of L.

The force shall be applied to the major, upper and longitudinal members except when a post structure is used without the cantilevered overhead shield. For this type of structure, the force shall be applied in line with the upper cross-member.

3.4.2.3.   The initial direction of the force shall be horizontal and perpendicular to a vertical plane through the tractor's longitudinal centre-line

3.4.2.4.   As loading continues, the deformations of the protective structure - tractor frame assembly may cause the direction of the force to change; this is permissible.

3.4.2.5.   Should the operator's seat be off the tractor's longitudinal centre-line, the loading shall be against the outermost side nearest the seat.

3.4.2.6.   For on-centre-line seats, if mounting of the protective structure is such that different force-deflection relations are obtained from loading from left or right sides, the side loaded shall be that which will place the most severe requirements on the protective structure - tractor frame assembly.

3.4.2.7.   The rate of deflection (application of load) shall be such that it can be considered static, i.e. less than or equal to 5 mm/s.

3.4.2.8.   At deflection increments no greater than 25 mm at the point of application of the resultant load, the force and deflection shall be recorded and plotted (Figure 8.17).

3.4.2.9.   The loading shall be continued until the protective structure has achieved both the force and energy requirements. The area under the resulting force-deflection curve (Figure 8.17) equals the energy.

3.4.2.10.   The deflection used in calculating energy shall be that of the protective structure along the line of action of the force. The deflection should be measured at the mid-point of the loading.

3.4.2.11.   Any deflection of members used to support load-application devices shall not be included in deflection measurements used for calculation of energy absorption.

3.4.3.   Vertical loading

3.4.3.1.   After removal of the side load, a vertical load shall be applied to the top of the protective structure.

3.4.3.2.   The load shall be applied using a stiff beam with a width of 250 mm.

3.4.3.3.   For structures having more than two posts, the vertical load shall be applied at both the front and the rear

3.4.3.3.1.   Vertical loading at the rear (Figures 8.10, 8.11.a and 8.11.b)

3.4.3.3.2.   Vertical loading at the front (Figures 8.10 to 8.12)

3.4.3.4.   For a protective structure having a two-post system, the vertical loading shall be dictated by the total longitudinal distance between major upper protective structure members L and the vertical projection of the front and rear planes of the DLV. The force (load) point shall be at a distance not less than L/3 distance from the posts (see Figure 8.9).

Should the L/3 point be between the vertical projection of the DLV and the posts, the force (load) point shall be moved away from the post until it enters the vertical projection of the DLV.

For front-mounted protective structures having a two-post system without an overhead shield, the vertical loading shall be applied in line with the transverse member connecting the upper members.

3.4.4.   Longitudinal loading

3.4.4.1.   After removal of the vertical load, a longitudinal load shall be applied to the protection structure.

3.4.4.2.   The longitudinal load shall be applied at the deformed location of the originally established point, since the lateral (and vertical) loading of the protection structure is likely to result in permanent deformation of the structure. The originally established point is determined by the location of the load distributor and socket prior to any test being performed on the structure.

The load distribution device may span the width in cases where no rear (front) cross-member exists. In all other cases, the device may not distribute the load over a length greater than 80 % of the width, W, of the protection structure (see Figure 8.18).

3.4.4.3.   The longitudinal load shall be applied to the upper structural members of the protection structure along the longitudinal centreline of the protection structure.

3.4.4.4.   The direction of loading shall be selected to place the most severe requirements on the protection structure/tractor frame assembly. The initial direction of loading shall be horizontal and parallel to the original longitudinal centreline of the tractor. Some additional factors to consider in deciding on the direction to apply the longitudinal load are:

3.4.4.5.   The rate of deflection shall be such that the loading may be considered static (see 3.4.2.7). This loading is to continue until the protection structure has achieved the force requirement(s)

3.5.   Conditions for acceptance

3.5.1.   General

3.5.1.1.   During each test, no part of the protective structure shall enter the deflection-limiting volume. Also, the deformation of the protective structure shall not allow the simulated ground plane (defined in paragraphs 1.11 and 1.12) to enter the DLV.

3.5.1.2.   The protective structure deflection during each test shall not cause the load side planes of the DLV to extend beyond or intersect the simulated ground plane (see Figures 8.19 and 8.20).

The protective structure shall not break away from the tractor frame due to failure of the tractor frame.

3.5.2.   Requirements for the side loading force-energy, the vertical loading force and the longitudinal loading force

3.5.2.1.   These requirements shall be met within the deflection(s) permitted in 3.5.1.1.

3.5.2.2.   The side-load force and the minimum energy absorbed shall attain at least those given in Table 8.1, where:

If the required force is attained before the energy requirement is met, the force may decrease but shall again attain the required level when the minimum energy is obtained or exceeded.

3.5.2.3.   After removal of the side load, the protective structure-tractor frame assembly shall support a vertical force:

for a period of 5 min or until any deformation has ceased, whichever is shorter.

3.5.2.4.   The longitudinal-load force shall attain at least that given in Table 8.1, where F and M are defined at point 3.5.2.2.

3.6.   Extension to other tractor models

3.6.1.   [Not applicable]

3.6.2.   Technical extension

When technical modifications occur on the tractor, the protective structure or the method of attachment of the protective structure to the tractor, the testing station that has carried out the original test can issue a ‘technical extension report’ in the following cases:

3.6.2.1.   Extension of the structural test results to other models of tractors

The impact and crushing tests need not be carried out on each model of tractor, provided that the protective structure and tractor comply with the conditions referred to hereunder 3.6.2.1.1 to 3.6.2.1.5.

3.6.2.2.   Extension of the structural test results to modified models of the protective structure

This procedure has to be followed when the provisions of paragraph 3.6.2.1 are not fulfilled, it may not be used when the method of attachment of the protective structure to the tractor does not remain of the same principle (e.g. rubber supports replaced by a suspension device):

3.7.   [Not applicable]

3.8.   Cold weather performance of protective structures

3.8.1.   If the protective structure is claimed to have properties resistant to cold weather embrittlement, the manufacturer shall give details which shall be included in the report.

3.8.2.   The following requirements and procedures are intended to provide strength and resistance to brittle fracture at reduced temperatures. It is suggested that the following minimum material requirements shall be met in judging the protective structure's suitability at reduced operating temperatures in those countries requiring this additional operating protective.

3.8.2.1.   Bolts and nuts used to attach the protective structure to the tractor and used to connect structural parts of the protective structure shall exhibit suitable controlled reduced temperature toughness properties.

3.8.2.2.   All welding electrodes used in the fabrication of structural members and mounts shall be compatible with the protective structure material as given in 3.8.2.3 below

3.8.2.3.   Steel materials for structural members of the protective structure shall be of controlled toughness material exhibiting minimum Charpy V-Notch impact energy requirements as shown in Table 8.2. Steel grade and quality shall be specified in accordance with ISO 630:1995; Amd1:2003.

Steel with an as-rolled thickness less than 2,5 mm and with a carbon content less than 0,2 per cent is considered to meet this requirement.

Structural members of the protective structure made from materials other than steel shall have equivalent low temperature impact resistance.

3.8.2.4.   When testing the Charpy V-Notch impact energy requirements, the specimen size shall be no less than the largest of the sizes stated in Table 8.2 that the material will permit

3.8.2.5.   The Charpy V-Notch tests shall be made in accordance with the procedure in ASTM A 370-1979, except for specimen sizes which shall be in accordance with the dimensions given in table 8.2.

3.8.2.6.   Alternatives to this procedure are the use of killed or semi-killed steel for which an adequate specification shall be provided. Steel grade and quality shall be specified in accordance with ISO 630:1995; Amd1:2003

3.8.2.7.   Specimens are to be longitudinal and taken from flat stock, tubular or structural sections before forming or welding for use in the protective structure. Specimens from tubular or structural sections are to be taken from the middle of the side of greatest dimension and shall not include welds

Table 8.1

Force and energy equations

Table 8.2

Minimum Charpy V-notch impact energies

Figure 8.1

Apparatus for determination of seat index point (SIP)

Figure 8.2

Intrusion of vertical simulated ground plane into DLV

Figure 8.3

Deflection-limiting volume (DLV)

Figure 8.4

Two-post front-mounted protective structure, side view

Deflection-limiting volume (DLV)

Figure 8.5

Two-post front-mounted protective structure, rear view

Deflection-limiting volume (DLV)

Figure 8.6

Typical arrangement for fastening the protective structure to the tractor frame

Figure 8.7

Typical arrangement for protective structure side loading

Figure 8.8

Typical arrangement for fixing the tractor frame and applying vertical load

Figure 8.9

Typical arrangement for applying vertical load to the protective structure

Figure 8.10

Example of an arrangement for crushing test

Figures 8.11

Position of beam for front and rear crushing tests, protective cab and rear roll bar frame

Figure 8.11.a

Protective cab

Figure 8.11.b

Rear roll bar frame

Figures 8.12

Position of beam for front crushing test when full crushing force not sustained in front

Figure 8.12.a

Protective cab

Figure 8.12.b

Rear roll bar frame

Figures 8.13 and 8.14

Structure with four-post system Load-distribution devices, side loading

Figure 8.15

Structure with more than a four-post system

Load-distribution device, side loading

Figure 8.16

Structure with two-post system

Load-distribution device, side loading

Figure 8.17

Force-deflection curve for loading tests

Figure 8.18

Longitudinal load application point

Figure 8.19

Deflection-limiting volume (DLV) application - determination of the lateral simulated ground plane (SGP)

Figure 8.20

Allowable rotation of upper DLV about locating axis (LA)

Explanatory notes to Annex VII

• (1) 

  Indicates preferred size. Specimen size shall be no less than largest preferred size that the material permits.

• (2) 

  The energy requirement at – 20 °C is 2,5 times the value specified for – 30 °C. Other factors affect impact energy strength, i.e. direction of rolling, yield strength, grain orientation and welding. These factors shall be considered when selecting and using steel.

ANNEX VIII

Requirements applying to roll-over protection structures (static testing)

• A. 

  GENERAL PROVISION

• B. 

  REQUIREMENTS APPLYING TO ROLL-OVER PROTECTION STRUCTURES (STATIC TESTING)(1)

• 1. 

  Definitions

1.1.   [Not applicable]

1.2.   Roll-Over Protective Structure (ROPS)

Roll-over protective structure (protective cab or frame), hereinafter called ‘protective structure’, means the structure on a tractor the essential purpose of which is to avoid or limit risks to the driver resulting from roll-over of the tractor during normal use.

The roll-over protective structure is characterised by the provision of space for a clearance zone large enough to protect the driver when seated either inside the envelope of the structure or within a space bounded by a series of straight lines from the outer edges of the structure to any part of the tractor that might come into contact with flat ground and that is capable of supporting the tractor in that position if the tractor overturns.

1.3.   Track

1.3.1.   Preliminary definition: median plane of the wheel or track

The median plane of the wheel or track is equidistant from the two planes containing the periphery of the rims or tracks at their outer edges.

1.3.2.   Definition of track

The vertical plane through the wheel axis intersects its median plane along a straight line which meets the supporting surface at one point. If A and B are the two points thus defined for the wheels on the same axle of the tractor, then the track width is the distance between points A and B. The track may be thus defined for both front and rear wheels. Where there are twin wheels, the track is the distance between two planes each being the median plane of the pairs of wheels.

For track-laying tractors, the track is the distance between the median planes of the tracks.

1.3.3.   Additional definition: median plane of the tractor

Take the extreme positions of points A and B for the tractor rear axle, which gives the maximum possible value for the track. The vertical plane at right angles to the line AB at its centre point is the median plane of the tractor.

1.4.   Wheelbase

The distance between the vertical planes passing through the two lines AB as defined above, one for the front wheels and one for the rear-wheels.

1.5.   Determination of seat index point; Seat location and adjustment for test

1.5.1.   Seat index point (SIP)(2)

The seat index point shall be determined in accordance with ISO 5353:1995

1.5.2.   Seat location and adjustment for test

1.6.   Clearance zone

1.6.1.   Reference plane for seat and steering wheel

The clearance zone is illustrated in figures 4.11 to 4.13 and Table 4.2. The zone is defined in relation to the reference plane and the Seat Index Point. The reference plane is defined at the beginning of the series of loadings; it is a vertical plane, generally longitudinal to the tractor and passing through the Seat Index Point and the centre of the steering wheel. Normally the reference plane coincides with the longitudinal median plane of the tractor. This reference plane shall be assumed to move horizontally with the seat and steering wheel during loading but to remain perpendicular to the tractor or the floor of the roll-over protective structure. The clearance zone shall be defined on the basis of Sections 1.6.2 and 1.6.3 below.

1.6.2.   Determination of the clearance zone for tractors with a non-reversible seat

The clearance zone for tractors with a non-reversible seat is defined in 1.6.2.1 to 1.6.2.10 below and is bounded by the following planes, the tractor being on a horizontal surface, the seat adjusted and located as specified in Sections 1.5.2.1 to 1.5.2.4(2), and the steering wheel, where adjustable, adjusted to the mid position for seated driving:

1.6.3.   Determination of clearance zone for tractors with a reversible driver’s position

For tractors with a reversible driver’s position (reversible seat and steering wheel), the clearance zone is the envelope of the two clearance zones defined by the two different positions of the steering wheel and the seat.

1.6.4.   Optional seats

1.7.   Mass

1.7.1.   Unballasted Mass

The mass of the tractor without ballasting devices and, in the case of tractors with pneumatic tyres, without liquid ballast in the tyres. The tractor shall be in running order with tanks, circuits and radiator full, protective structure with cladding and any track equipment or additional front wheel drive components required for normal use. The operator is not included.

1.7.2.   Maximum Permissible Mass

The maximum mass of the tractor stated by the manufacturer to be technically permissible and declared on the vehicle’s identification plate and/or in the Operator’s Handbook;

1.7.3.   Reference Mass

The mass selected by the manufacturer for calculation of the energy inputs and crushing forces to be used in the tests. Must not be less than the unballasted mass and must be sufficient to ensure the Mass Ratio does not exceed 1,75 (see Section 1.7.4).

1.7.4.   Mass Ratio

The ratio of This must not be greater than 1,75.

1.8.   Permissible measurement tolerances

1.9.   Symbols

• 2. 

  Field of application

• 3. 

  Rules and directions

3.1.   General regulations

3.2.   Apparatus

For verifying that the clearance zone has not been entered during the test, means shall be used as described in point 1.6, figures 4.11 to 4.13 and Table 4.2.

3.2.1.   Horizontal loading tests (figures 4.1 to 4.5)

The following shall be used in horizontal loading tests:

3.2.2.   Crushing tests (figures 4.6 to 4.8)

The following shall be used in crushing tests:

3.3.   Test conditions

3.3.1.   The protective structure shall be to production specifications and shall be fitted to the appropriate tractor model chassis in accordance with the manufacturer's declared method of attachment.

3.3.2.   The assembly shall be secured to the bedplate so that the members connecting the assembly and the bedplate do not deflect significantly in relation to the protective structure under load. The assembly shall not receive any support under load other than that due to the initial attachment.

3.3.3.   An adjustable track width setting for the wheels or tracks, if present, shall be chosen such that no interference exists with the protective structure during the tests.

3.3.4.   The protective structure shall be instrumented with the necessary equipment to obtain the required force-deflection data.

3.3.5.   All tests shall be performed on the same protective structure. No repairs or straightening of any members shall be carried out between any parts of the test

3.3.6.   On completion of all tests, permanent deflections of the protective structure shall be measured and recorded.

3.4.   Sequence of tests

Tests shall be conducted in the following sequence:

3.4.1.   Longitudinal loading

For a wheeled tractor with at least 50 % of its mass on the rear axle and for track-laying tractors, the longitudinal loading shall be applied from the rear. For other tractors the longitudinal loading shall be applied from the front.

3.4.2.   First crushing test

The first crushing test shall be applied at the same end of the protective structure as the longitudinal loading

3.4.3.   Loading from the side

In the case of an offset seat or non-symmetrical strength of the protective structure, the side loading shall be on the side most likely to lead to infringement of the clearance zone.

3.4.4.   Second crushing test

The second crushing test shall be applied at the end of the protective structure opposite from that receiving the first longitudinal loading. In the case of two-post designs, the second crush may be at the same point as the first crush.

3.4.5.   Second longitudinal loading

3.5.   Horizontal loading tests from the rear, front and side

3.5.1.   General provisions

3.5.2.   Longitudinal loading (figures 4.1 and 4.2)

The load shall be applied horizontally and parallel to the median plane of the tractor. If the load is applied from the rear (Section 3.4.1), the longitudinal load and the lateral load shall be applied on different sides of the median plane of the tractor. If the longitudinal load is applied from the front, it shall be on the same side as the side load.

The load shall be applied to the uppermost transverse structural member of the protective structure (i.e. that part which would be likely to strike the ground first in an overturn).

The point of application of the load shall be located at one sixth of the width of the top of the protective structure inwards from the outside corner. The width of the protective structure shall be taken as the distance between two lines parallel to the median plane of the tractor touching the outside extremities of the protective structure in the horizontal plane touching the top of the uppermost transverse structural members.

In the event that the ROPS is formed of curved members and no appropriate corners exist, the following general procedure shall apply for determining W. The test engineer shall identify the curved member most likely to first strike ground in the event of an asymmetrical rear or front overturn (e.g. an overturn to the front or rear where one side of the ROPS is likely to bear the initial loading). The endpoints of W shall be the mid-points of the external radii created between other straight or curved members which form the uppermost ROPS structure. In the event that multiple curved members could be selected, the test engineer shall establish ground lines for each possible member to determine which surface is most likely to strike ground first. See figures 4.3 a) and b) for examples.

Note:

In the event of curved members, only the width at the end of the structure to which the longitudinal load is to be applied need be considered

The length of the load distribution device (see 3.2.1.2) shall be not less than one third of the width of the protective structure and not more than 49 mm greater than this minimum.

The longitudinal loading shall be stopped when:

3.5.3.   Side loading (figures 4.4 and 4.5)

The side loading shall be applied horizontally at 90° to the median plane of the tractor. It shall be applied to the upper extremity of the protective structure at a point (160 – ah ) mm forward of the Seat Index Point.

For tractors with a reversible driver's position (reversible seat and steering wheel), it shall be applied to the upper extremity of the protective structure at the mid-point between the two Seat Index Points.

If it is certain that any particular part of the protective structure will touch ground first when the tractor overturns sideways, the loading shall be applied at that point, provided that this permits uniform distribution of the load as specified in 3.5.1.1. In the case of a two-post protective structure, side loading shall be applied at the structural member uppermost on the side, regardless of the seat index position.

Specifications for the load distribution beam are given in Section 3.2.1.2.1.

The side loading shall be stopped when:

3.6.   Crushing tests

3.6.1.   Crushing at the rear (figures 4.6, 4.7.a to 4.7.e)

3.6.2.   Crushing at the front (figures 4.6 to 4.8)

3.7.   Second longitudinal loading test

The load shall be applied in the opposite direction to and at the corner farthest from the point of application of the first longitudinal load (figures 4.1 and 4.2).

The longitudinal loading shall be stopped when:

3.8.   Conditions for acceptance

For the protective structure to be accepted it shall fulfil the following conditions during and after completion of the tests:

3.9.   Extension to other tractor models

3.9.1.   [Not applicable]

3.9.2.   Technical extension

When technical modifications occur on the tractor, the protective structure or the method of attachment of the protective structure to the tractor, the testing station that has carried out the original test can issue a ‘technical extension report’ in the following cases:

3.10.   [Not applicable]

3.11.   Cold weather performance of protective structures

3.12.   [Not applicable]

Figure 4.1

Front and rear load applications, Protective cab and rear roll bar frame

(Dimensions in mm)

Figure 4.1.a

Protective cab

Figure 4.1.b

Rear roll bar frame

Figure 4.2

Longitudinal load applications

Figure 4.3

Examples of ‘W’ for ROPS with curved members

Figure 4.3.a

Four-post ROPS

Key:

1— Seat index point

2— SIP, longitudinal centre-plane

3— Point of second longitudinal load application, front or rear

4— Point of longitudinal load application, rear or front

Figure 4.3.b

Two-post ROPS

Key:

1— Seat index point (SIP)

2— SIP, longitudinal centre-plane

3— Point of second longitudinal load application, front or rear

4— Point of longitudinal load application, rear or front

Figure 4.4

Side load application (side view), protective cab and rear roll bar frame

Figure 4.4.a

Protective cab

Figure 4.4.b

Rear roll bar frame

Figure 4.5

Side load application (rear view)

Figure 4.6

Example of arrangement for crushing test

Figure 4.7

Position of beam for front and rear crushing tests, protective cab and rear roll bar frame

Figure 4.7.a

Rear Crush

Figure 4.7.b

Front Crush

Figure 4.7.c

Crush test for rear roll bar

Figure 4.7.d

Protective cab

Figure 4.7.e

Rear roll bar frame

Figure 4.8

Position of beam for front crushing test when full crushing force not sustained in front

Figure 4.8.a

Protective cab

Figure 4.8.b

Rear roll bar frame

Figure 4.9

The crushing force is applied with the beam having its centre point passing in the vertical reference plane of the tractor (being also that of the seat and steering wheel)

In these cases, the vertical reference plane referred to the seat and steering wheel includes normally also the centre of gravity of the tractor during the execution of the entire series of loadings.

Figure 4.10

The crushing force is applied with the beam having its centre point passing only in the vertical reference plane of the tractor

Cases 3 and 4 can be defined, in which the ROPS is fixed to a platform, rigidly fixed (case 3) or suspended (case 4) in respect to the tractor chassis. These joining or linkage solutions cause different movements to cabs and clearance zone as well as the vertical reference plane.

Table 4.2

Dimensions of the clearance zone

Figure 4.11

Clearance zone

Key:

Figure 4.12

Clearance zone

Figure 4.12.a

Side view section in reference plan

Figure 4.12.b

Rear or front view

Key:

1— Seat index point

2— Force

3— Vertical reference plane

Figure 4.13

Clearance zone for tractor with reversible seat and steering wheel, protective cab and rear roll bar frame

Figure 4.13.a

Protective cab

Figure 4.13.b

Rear roll bar frame

Figure 4.14

Force/deflection curve

Overload test not necessary

Notes:

Figure 4.15

Force/deflection curve

Overload test necessary

Notes:

Figure 4.16

Force/deflection curve

Overload test to be continued

Notes:

Explanatory notes to Annex VIII

• (1) 

  Indicates preferred size. Specimen size shall be no less than largest preferred size that the material permits.

• (2) 

  The energy requirement at – 20 °C is 2,5 times the value specified for – 30 °C. Other factors affect impact energy strength, i.e. direction of rolling, yield strength, grain orientation and welding. These factors shall be considered when selecting and using steel.

ANNEX IX

Requirements applying to roll-over protection structures (front mounted roll-over protective structures on narrow-track tractors)

• A. 

  GENERAL PROVISIONS

• B. 

  REQUIREMENTS APPLYING TO ROLL-OVER PROTECTION STRUCTURES (FRONT MOUNTED ROLL-OVER PROTECTIVE STRUCTURES ON NARROW-TRACK TRACTORS)(1)

• 1. 

  Definitions

1.1   [Not applicable]

1.2.   Roll-Over Protective Structure (ROPS)

Roll-over protective structure (protective cab or frame), hereinafter called ‘protective structure’, means the structure on a tractor the essential purpose of which is to avoid or limit risks to the driver resulting from roll-over of the tractor during normal use.

The roll-over protective structure is characterized by the provision of space for a clearance zone large enough to protect the driver when seated either inside the envelope of the structure or within a space bounded by a series of straight lines from the outer edges of the structure to any part of the tractor that might come into contact with flat ground and that is capable of supporting the tractor in that position if the tractor overturns.

1.3.   Track

1.3.1.   Preliminary definition: median plane of the wheel

The median plane of the wheel is equidistant from the two planes containing the periphery of the rims at their outer edges.

1.3.2.   Definition of track

The vertical plane through the wheel axis intersects its median plane along a straight line which meets the supporting surface at one point. If A and B are the two points thus defined for the wheels on the same axle of the tractor, then the track width is the distance between points A and B. The track may be thus defined for both front and rear wheels. Where there are twin wheels, the track is the distance between two planes each being the median plane of the pairs of wheels.

1.3.3.   Additional definition: median plane of the tractor

Take the extreme positions of points A and B for the tractor rear axle, which gives the maximum possible value for the track. The vertical plane at right angles to the line AB at its centre point is the median plane of the tractor.

1.4.   Wheelbase

The distance between the vertical planes passing through the two lines AB as defined above, one for the front wheels and one for the rear-wheels.

1.5.   Determination of seat index point; seat location and adjustment for test

1.5.1.   Seat index point (SIP)(2)

The seat index point shall be determined in accordance with ISO 5353:1995

1.5.2.   Seat location and adjustment for test

1.6.   Clearance zone

1.6.1.   Reference vertical plane and line

The clearance zone (figure 6.1) is defined on the basis of a vertical reference plane and a reference line:

1.6.2.   Determination of the clearance zone for tractors with a non-reversible seat

The clearance zone for tractors with a non-reversible seat is defined in 1.6.2.1 to 1.6.2.11 below and is bounded by the following planes, the tractor being on a horizontal surface, the seat adjusted and located as specified in sections 1.5.2.1 to 1.5.2.4(3), and the steering wheel, where adjustable, adjusted to the mid position for seated driving:

1.6.3.   Determination of the clearance zone for tractors with a reversible driver’s position

For tractors with a reversible driver’s position (reversible seat and steering wheel), the clearance zone is the envelope of the two clearance zones defined by the two different positions of the steering wheel and the seat. For each position of steering wheel and the seat the clearance zone shall respectively be defined on the basis of above sections 1.6.1 and 1.6.2 for driver’s position in normal position and on the basis of sections 1.6.1 and 1.6.2 of Annex X for driver’s position in reverse position (see figure 6.2).

1.6.4.   Optional seats

1.7.   Mass

1.7.1.   Unballasted / Unladen Mass

The mass of the tractor excluding optional accessories but including coolant, oils, fuel, tools plus the protective structure. Not included are optional front or rear weights, tyre ballast, mounted implements, mounted equipment or any specialised components;

1.7.2.   Maximum Permissible Mass

The maximum mass of the tractor stated by the manufacturer to be technically permissible and declared on the vehicle’s identification plate and/or in the Operator’s Handbook;

1.7.3.   Reference Mass

The mass, selected by the manufacturer, used in formulae to calculate the height of fall of the pendulum block, the energy inputs and crushing forces to be used in the tests. Must not be less than the unballasted mass and must be sufficient to ensure the Mass Ratio does not exceed 1,75 (see Sections 1.7.4 and 2.1.3);

1.7.4.   Mass Ratio

The ratio of This must not be greater than 1,75.

1.8.   Permissible measurement tolerances

1.9.   Symbols

• 2. 

  Field of application

B1.   STATIC TEST PROCEDURE

• 3. 

  Rules and directions

3.1.   Prior conditions for the strength tests

3.1.1.   Completion of two preliminary tests

The protective structure may only be subjected to the strength tests if both the Lateral Stability Test and the Non-Continuous Rolling Test have been satisfactorily completed (see flow diagram as figure 6.3).

3.1.2.   Preparation for the preliminary tests

3.1.2.1.   The tractor must be equipped with the protective structure in its safety position.

3.1.2.2.   The tractor must be fitted with tyres having the greatest diameter indicated by the manufacturer and the smallest cross-section for tyres of that diameter. The tyres must not be liquid-ballasted and must be inflated to the pressure recommended for field work.

3.1.2.3.   The rear wheels must be set to the narrowest track width; the front wheels must be set as closely as possible to the same track width. If it is possible to have two front track settings which differ equally from the narrowest rear track setting, the wider of these two front track settings must be selected.

3.1.2.4.   All the tractor’s tanks must be filled or the liquids must be replaced by an equivalent mass in the corresponding position.

3.1.2.5.   All attachments used in the series production shall be fixed to the tractor in the normal position.

3.1.3.   Lateral stability test

3.1.3.1.   The tractor, prepared as specified above, is placed on a horizontal plane so that the tractor front-axle pivot point or, in the case of an articulated tractor, the horizontal pivot point between the two axles can move freely.

3.1.3.2.   Using a jack or a hoist, tilt the part of the tractor which is rigidly connected to the axle that bears more than 50 per cent of the tractor’s weight, while constantly measuring the angle of inclination. This angle must be at least 38° at the moment when the tractor is resting in a state of unstable equilibrium on the wheels touching the ground. Perform the test once with the steering wheel turned to full right lock and once with the steering wheel turned to full left lock.

3.1.4.   Non-continuous rolling test

3.1.4.1.   General remarks

This test is intended to check whether a structure fitted to the tractor for the protection of the driver can satisfactorily prevent continuous roll-over of the tractor in the event of its overturning laterally on a slope with a gradient of 1 in 1.5 (figure 6.4).

Evidence of non-continuous rolling can be provided in accordance with one of the two methods described in 3.1.4.2 and 3.1.4.3.

3.1.4.2.   Demonstration of non-continuous rolling behaviour by means of the overturning test

3.1.4.3.   Demonstration of non-continuous rolling behaviour by calculation

3.1.5.   Measurement methods

3.1.5.1.   Horizontal distances between the centre of gravity and rear (L3) or front (L2) axles

The distance between the rear and front axles on both sides of the tractor shall be measured in order to verify there is no steering angle.

The distances between the centre of gravity and the rear axle (L3) or the front axle (L2) shall be calculated from the mass distribution of the tractor between the rear and the front wheels.

3.1.5.2.   Heights of rear (D3) and front (D2) tyres

The distance from the highest point of the tyre to the ground plane shall be measured (figure 6.5), and the same method shall be used for the front and rear tyres.

3.1.5.3.   Horizontal distance between the centre of gravity and the leading point of intersection of the protective structure (L6).

The distance between the centre of gravity and the leading point of intersection of the protective structure shall be measured (figures 6.6.a, 6.6.b and 6.6.c). If the protective structure is in front of the plane of the centre of gravity, the recorded measure will be preceded by a minus sign (– L6).

3.1.5.4.   Width of the protective structure (B6)

The distance between the right and left points of impact of the two vertical posts of the structure shall be measured.

The point of impact is defined by the plane tangent to the protective structure passing through the line made by the top outer points of the front and rear tyres (figure 6.7).

3.1.5.5.   Height of the protective structure (H6)

The vertical distance from the point of impact of the structure to the ground plane shall be measured.

3.1.5.6.   Height of the engine bonnet (H7)

The vertical distance from the point of impact of the engine bonnet to the ground plane shall be measured.

The point of impact is defined by the plane tangent to the engine bonnet and the protective structure passing through the top outer points of the front tyre (figure 6.7). The measurement shall be made on both sides of the engine bonnet.

3.1.5.7.   Width of the engine bonnet (B7)

The distance between the two points of impact of the engine bonnet as defined previously shall be measured.

3.1.5.8.   Horizontal distance between the centre of gravity and the front corner of the engine bonnet (L7)

The distance from the point of impact of the engine bonnet, as defined previously, to the centre of gravity shall be measured.

3.1.5.9.   Height of the front-axle pivot point (H0)

The vertical distance between the centre of the front-axle pivot point to the centre of axle of the front tyres (H01) shall be included in the manufacturer’s technical report and shall be checked.

The vertical distance from the centre of the front tyres axle to the ground plane (H02) shall be measured (figure 6.8).

The height of the front-axle pivot (H0) is the sum of both previous values.

3.1.5.10.   Rear track width (S)

The minimum rear track width fitted with tyres of the largest size, as specified by the manufacturer, shall be measured (figure 6.9).

3.1.5.11.   Rear tyre width (B0)

The distance between the outer and the inner vertical planes of a rear tyre in its upper part shall be measured (figure 6.9).

3.1.5.12.   Front axle swinging angle (D0)

The largest angle defined by the swinging of the front axle from the horizontal position to the maximum deflection shall be measured on both sides of the axle, taking into account any end-stroke shock absorber. The maximum angle measured shall be used.

3.1.5.13.   Tractor Mass

The tractor mass shall be determined according to the conditions specified in section 1.7.1.

3.2.   Conditions for testing the strength of protective structures and of their attachment to tractors

3.2.1.   General requirements

3.2.1.1.   Test purposes

Tests made using special rigs are intended to simulate such loads as are imposed on a protective structure, when the tractor overturns. These tests enable observations to be made on the strength of the protective structure and any brackets attaching it to the tractor and any parts of the tractor which transmit the test load.

3.2.1.2.   Test methods

Tests may be performed in accordance with the static procedure or the dynamic procedure (see Annex A). The two methods are deemed equivalent.

3.2.1.3.   General rules governing preparation for tests

3.2.2.   Tests

3.2.2.1.   Sequence of tests according to the Static Procedure

The sequence of tests, without prejudice to the additional tests mentioned in sections 3.3.1.6, and 3.3.1.7 is as follows:

3.2.2.2.   General requirements

3.2.3.   Acceptance conditions

3.2.3.1.   A protective structure is regarded as having satisfied the strength requirements if it fulfils the following conditions:

3.2.3.2.   There shall be no accessories presenting a hazard for the driver. There shall be no projecting part or accessory which is liable to injure the driver should the tractor overturn, or any accessory or part which is liable to trap him — for example by the leg or the foot — as a result of the deflections of the structure.

3.2.4.   [Not applicable]

3.2.5.   Test apparatus and equipment

3.2.5.1.   Static testing rig

3.2.5.2.   Apparatus for measuring the energy absorbed by the structure

3.2.5.3.   Means of anchoring the tractor to the ground

3.2.5.4.   Crushing rig

A rig as shown in figure 6.10 shall be capable of exerting a downward force on a protective structure through a rigid beam approximately 250 mm wide, connected to the load-applying mechanism by means of universal joints. Suitable axle stands must be provided so that the tractor tyres do not bear the crushing force.

3.2.5.5.   Other measuring apparatus

The following measuring devices are also needed:

3.3.   Static test procedure

3.3.1.   Loading and crushing tests

3.3.1.1.   Loading at the rear

3.3.1.2.   Loading at the front

3.3.1.3.   Loading from the side

3.3.1.4.   Crushing at the rear

The beam shall be positioned over the rear uppermost structural member(s) and the resultant of crushing forces shall be located in the tractor’s median plane. A force Fv shall be applied where:

The force Fv shall be maintained for five seconds after cessation of any visually detectable movement of the protective structure.

Where the rear part of the protective structure roof will not sustain the full crushing force, the force shall be applied until the roof is deflected to coincide with the plane joining the upper part of the protective structure with that part of the rear of the tractor capable of supporting the tractor when overturned.

The force shall then be removed, and the crushing beam repositioned over that part of the protective structure which would support the tractor when completely overturned. The crushing force Fv shall then be applied again.

3.3.1.5.   Crushing at the front

The beam shall be positioned across the front uppermost structural member(s) and the resultant of crushing forces shall be located in the tractor’s median plane. A force Fv shall be applied where:

The force Fv shall be maintained for five seconds after the cessation of any visually detectable movement of the protective structure.

Where the front part of the protective structure roof will not sustain the full crushing force, the force shall be applied until the roof is deflected to coincide with the plane joining the upper part of the protective structure with that part of the front of the tractor capable of supporting the tractor when overturned.

The force shall then be removed, and the crushing beam repositioned over that part of the protective structure which would support the tractor when completely overturned. The crushing force Fv shall then be applied again.

3.3.1.6.   Additional overload test (figures 6.14 to 6.16)

An overload test shall be carried out in all cases where the force decreases by more than 3 per cent during the last 5 per cent of the deflection reached when the energy required is absorbed by the structure (see figure 6.15).

The overload test involves the gradual increase of the horizontal load by increments of 5 per cent of the initial energy requirement up to a maximum of 20 per cent of energy added (see figure 6.16).

The overload test is satisfactory if, after each increase by 5, 10 or 15 per cent in the energy required, the force decreases by less than 3 per cent for a 5 per cent increment and remains greater than 0,8 Fmax.

The overload test is satisfactory if, after the structure has absorbed 20 per cent of the added energy, the force exceeds 0,8 Fmax.

Additional cracks or tears and/or entry into or lack of protection of the clearance zone due to elastic deflection are permitted during the overload test. However, after the removal of the load, the structure shall not enter the clearance zone, which shall be completely protected.

3.3.1.7.   Additional crushing tests

If cracks or tears which cannot be considered as negligible appear during a crushing test, a second, similar crushing, but with a force of 1,2 Fv shall be applied immediately after the crushing test which caused the cracks or tears to appear.

3.3.2.   Measurements to be made

3.3.2.1.   Fractures and cracks

After each test all structural members, joints and attachment systems shall be visually examined for fractures or cracks, any small cracks in unimportant parts being ignored.

3.3.2.2.   Entry into the clearance zone

During each test the protective structure shall be examined to see whether any part of it has entered the clearance zone as defined in 1.6 above.

Furthermore, the clearance zone shall not be outside the protection of the protective structure. For this purpose, it shall be considered to be outside the protection of the structure if any part of it would come in contact with flat ground if the tractor overturned towards the direction from which the test load is applied. For estimating this, the front and rear tyres and track width setting shall be the smallest standard fitting specified by the manufacturer.

3.3.2.3.   Rear hard fixture tests

If the tractor is fitted with a rigid section, a housing or other hard fixture placed behind the driver’s seat, this fixture shall be regarded as a protective point, in the event of sideways or rear overturning. This hard fixture placed behind the driver’s seat shall be capable of withstanding, without breaking or entering the clearance zone, a downward force Fi, where:

applied perpendicularly to the top of the frame in the central plane of the tractor. The initial angle of application of force shall be 40° calculated from a parallel to the ground as shown in figure 6.12. The minimum width of this rigid section shall be 500 mm (see figure 6.13).

In addition, it shall be sufficiently rigid and firmly attached to the rear of the tractor.

3.3.2.4.   Elastic deflection under side loading

The elastic deflection shall be measured (810 + av ) mm above the Seat Index Point, in the vertical plane in which the load is applied. For this measurement, any apparatus similar to that illustrated in figure 6.11 shall be used.

3.3.2.5.   Permanent deflection

After the final crushing test the permanent deflection of the protective structure shall be recorded. For this purpose, before the start of the test, the position of the main roll-over protective structure members in relation to the Seat Index Point shall be recorded.

3.4.   Extension to other tractor models

3.4.1.   [Not applicable]

3.4.2.   Technical extension

When technical modifications occur on the tractor, the protective structure or the method of attachment of the protective structure to the tractor, the testing station that has carried out the original test can issue a ‘technical extension report’ if the tractor and protective structure satisfied preliminary tests of lateral stability and non-continuous rolling as defined in 3.1.3 and 3.1.4 and if the rear hard fixture as described in paragraph 3.3.2.3., when fitted, has been tested in accordance with the procedure described in this paragraph (except 3.4.2.2.4) in the following cases:

3.4.2.1.   Extension of the structural test results to other models of tractors

The impact or loading and crushing tests need not be carried out on each model of tractor, provided that the protective structure and tractor comply with the conditions referred to hereunder in 3.4.2.1.1 to 3.4.2.1.5.

3.4.2.2.   Extension of the structural test results to modified models of the protective structure

This procedure has to be followed when the provisions of section 3.4.2.1 are not fulfilled, it may not be used when the method of attachment of the protective structure to the tractor does not remain of the same principle (e.g. rubber supports replaced by a suspension device):

3.5.   [Not applicable]

3.6.   Cold weather performance of protective structures

3.6.1.   If the protective structure is claimed to have properties resistant to cold weather embrittlement, the manufacturer shall give details that shall be included in the report.

3.6.2.   The following requirements and procedures are intended to provide strength and resistance to brittle fracture at reduced temperatures. It is suggested that the following minimum material requirements shall be met in judging the protective structure’s suitability at reduced operating temperatures in those countries requiring this additional operating protection.

3.6.2.1.   Bolts and nuts used to attach the protective structure to the tractor and used to connect structural parts of the protective structure shall exhibit suitable controlled reduced temperature toughness properties.

3.6.2.2.   All welding electrodes used in the fabrication of structural members and mounts shall be compatible with the protective structure material as given in 3.6.2.3 below.

3.6.2.3.   Steel materials for structural members of the protective structure shall be of controlled toughness material exhibiting minimum Charpy V-Notch impact energy requirements as shown in Table 6.1. Steel grade and quality shall be specified in accordance with ISO 630:1995.

Steel with an as-rolled thickness less than 2,5 mm and with a carbon content less than 0,2 per cent is considered to meet this requirement.

Structural members of the protective structure made from materials other than steel shall have equivalent low temperature impact resistance.

3.6.2.4.   When testing the Charpy V-Notch impact energy requirements, the specimen size shall be no less than the largest of the sizes stated in Table 6.1 that the material will permit.

3.6.2.5.   The Charpy V-Notch tests shall be made in accordance with the procedure in ASTM A 370-1979, except for specimen sizes that shall be in accordance with the dimensions given in Table 6.1.

3.6.2.6.   Alternatives to this procedure are the use of killed or semi-killed steel for which an adequate specification shall be provided. Steel grade and quality shall be specified in accordance with ISO 630:1995, Amd 1:2003.

3.6.2.7.   Specimens are to be longitudinal and taken from flat stock, tubular or structural sections before forming or welding for use in the protective structure. Specimens from tubular or structural sections are to be taken from the middle of the side of greatest dimension and shall not include welds.

Table 6.1.

Minimum Charpy V-notch impact energies

3.7.   [Not applicable]

Figure 6.1

Clearance zone

Dimensions in mm

1– Reference line

2– Seat index point

3– Reference plane

Figure 6.2

Clearance zone for tractors with reversible seat and steering wheel

Figure 6.3

Flow diagram for determining the continuous roll-over behaviour of a laterally overturning tractor with a front mounted roll-over protective structure (ROPS)

Version B1: Point of impact of ROPS behind longitudinally unstable equilibrium point

Version B2: Point of impact of ROPS near longitudinally unstable equilibrium point

Version B3: Point of impact of ROPS in front of longitudinally unstable equilibrium point

Figure 6.4

Rig for testing anti-roll properties on 1/1,5 gradient

Figure 6.5

Data required for calculating the overturn of a tractor with triaxial rolling behaviour

Figures 6.6.a, 6.6.b, 6.6.c

Horizontal distance between the centre of gravity and the leading point of intersection of the protective structure (L6)

Figure 6.7

Determination of points of impact for measurement of width of protective structure (B6) and height of engine bonnet (H7)

Figure 6.8

Height of the front-axle pivot point (H0)

Figure 6.9

Rear track width (S) and Rear tyre width (B0)

Figure 6.10

Example of crushing rig of the tractor

Figure 6.11

Example of apparatus for measuring elastic deflection

1– Permanent deflection

2– Elastic deflection

3– Total deflection (permanent plus elastic)

Figure 6.12

Simulated ground line

Figure 6.13

Minimum width of the rear hard fixture

Figure 6.14

Force / deflection curve

Overload test not necessary

Notes:

Figure 6.15

Force / deflection curve

Overload test necessary

Notes:

Figure 6.16

Force / deflection curve

Overload test to be continued

Notes:

B2.   ALTERNATIVE ‘DYNAMIC’ TEST PROCEDURE

This section sets out the Dynamic Testing Procedure alternative to the static test procedure set out in section B1.

• 4. 

  Rules and directions

4.1.   Prior conditions for the strength tests

See requirements stated for static testing.

4.2.   Conditions for testing the strength of protective structures and of their attachment to tractors

4.2.1.   General requirements

See requirements stated for static testing.

4.2.2.   Tests

4.2.2.1.   Sequence of tests according to the Dynamic Procedure

The sequence of tests, without prejudice to the additional tests mentioned in sections 4.3.1.6 and 4.3.1.7 is as follows:

4.2.2.2.   General requirements

4.2.3.   Acceptance conditions

4.2.3.1.   A protective structure is regarded as having satisfied the strength requirements if it fulfils the following conditions: