Requirements applying to roll-over protection structures (rear mounted roll-over protective structures on narrow-track tractors)
A. GENERAL PROVISIONS
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1. |
The Union requirements applying to roll-over protection structures (rear mounted roll-over protective structures on narrow track tractors) are set out in point B. |
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2. |
Tests may be performed in accordance with the static or alternatively the dynamic test procedures as set out in sections B1 and B2. The two methods are deemed equivalent. |
B. REQUIREMENTS APPLYING TO ROLL-OVER PROTECTION STRUCTURES (REAR 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 or track.
The median plane of the wheel 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
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1.5.2.1. |
where the seat position is adjustable, the seat must be adjusted to its rear uppermost position; |
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1.5.2.2. |
where the inclination of the backrest is adjustable, it must be adjusted to the mid position; |
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1.5.2.3. |
where the seat is equipped with suspension, the latter must be blocked at mid-travel, unless this is contrary to the instructions clearly laid down by the seat manufacturer; |
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1.5.2.4. |
where the position of the seat is adjustable only lengthwise and vertically, the longitudinal axis passing through the Seat Index Point shall be parallel with the vertical longitudinal plane of the tractor passing through the centre of the steering wheel and not more than 100 mm from that plane. |
1.6. Clearance zone
1.6.1. Reference plane
The clearance zone is illustrated in figures 7.1 and 7.2. 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 Sections 1.6.2 and 1.6.3.
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 1.6.2.13 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:
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1.6.2.1. |
a horizontal plane A1 B1 B2 A2, (810 + a v) mm above the Seat Index Point with line B1B2 located (a h-10) mm behind the SIP; |
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1.6.2.2. |
an inclined plane H1 H2 G2 G1, perpendicular to the reference plane, including both a point 150 mm behind line B1B2 and the rearmost point of the seat backrest; |
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1.6.2.3. |
a cylindrical surface A1 A2 H2 H1 perpendicular to the reference plane, having a radius of 120 mm, tangential to the planes defined in 1.6.2.1 and 1.6.2.2 above; |
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1.6.2.4. |
a cylindrical surface B1 C1 C2 B2, perpendicular to the reference plane, having a radius of 900 mm extending forward for 400 mm and tangential to the plane defined in 1.6.2.1 above along line B1B2; |
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1.6.2.5. |
an inclined plane C1 D1 D2 C2, perpendicular to the reference plane, joining the surface defined in 1.6.2.4 above and passing 40 mm from the forward external edge of the steering wheel. In the case of a high steering wheel position, this plane extends forward from line B1B2 tangentially to the surface defined in 1.6.2.4 above; |
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1.6.2.6. |
a vertical plane D1 K1 E1 E2 K2 D2 perpendicular to the reference plane 40 mm forward of the external edge of the steering wheel; |
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1.6.2.7. |
a horizontal plane E1 F1 P1 N1 N2 P2 F2 E2 passing through a point (90-av ) mm below the Seat Index Point; |
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1.6.2.8. |
a surface G1 L1 M1 N1 N2 M2 L2 G2, if necessary curved from the bottom limit of the plane defined in 1.6.2.2 above to the horizontal plane defined in 1.6.2.7 above, perpendicular to the reference plane, and in contact with the seat backrest throughout its length; |
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1.6.2.9. |
two vertical planes K1 I1 F1 E1 and K2 I2 F2 E2 parallel to the reference plane, 250 mm either side of the reference plane, and bounded at the top 300 mm above the plane defined in 1.6.2.7 above; |
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1.6.2.10. |
two inclined and parallel planes A1 B1 C1 D1 K1 I1 L1 G1 H1 and A2 B2 C2 D2 K2 I2 L2 G2 H2 starting from the upper edge of the planes defined in 1.6.2.9 above and joining the horizontal plane defined in 1.6.2.1 above at least 100 mm from the reference plane on the side where the loading is applied; |
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1.6.2.11. |
two portions of vertical planes Q1 P1 N1 M1 and Q2 P2 N2 M2 parallel to the reference plane, 200 mm either side of the reference plane, and bounded towards the top 300 mm above the horizontal plane defined in 1.6.2.7 above |
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1.6.2.12. |
two portions of I1 Q1 P1 F1 and I2 Q2 P2 F2 of a vertical plane, perpendicular to the reference plane and passing (210-ah ) mm in front of the SIP; |
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1.6.2.13. |
two portions I1 Q1 M1 L1 and I2 Q2 M2 L2 of the horizontal plane passing 300 mm above the plane defined in 1.6.2.7 above. |
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.
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1.6.3.1. |
If the protective structure is a of a rear two-post type, for each position of the steering wheel and of 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 IX for driver’s position in reverse position (see figure 7.2.a). |
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1.6.3.2. |
If the protective structure is of another type, for each position of the steering wheel and of the seat, the clearance zone shall be defined on the basis of sections 1.6.1 and 1.6.2 of this Annex (see figure 7.2.b). |
1.6.4. Optional seats
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1.6.4.1. |
In case of tractors that could be fitted with optional seats, the envelope comprising the Seat Index Points of all options offered shall be used during the tests. The protective structure shall not enter the larger clearance zone which takes account of these different Seat Index Points. |
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1.6.4.2. |
In the case where a new seat option is offered after the test has been performed, a determination shall be made to see whether the clearance zone around the new SIP falls within the envelope previously established. If it does not, a new test must be performed. |
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1.6.4.3. |
Optional seat does not include a seat for a person in addition to the driver and from where the tractor cannot be controlled. The SIP shall not be determined because the definition of the clearance zone is in relation to the driver seat. |
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 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
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Linear dimension: |
± 3 mm |
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except for: – tyre deflection: |
± 1 mm |
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– structure deflection during horizontal loadings: |
± 1 mm |
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– height of fall of the pendulum block: |
± 1 mm |
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Masses: |
± 0,2 % (of the sensor full scale) |
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Forces: |
± 0,1 % (of the sensor full scale) |
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Angles: |
± 0,1° |
1.9. Symbols
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ah |
(mm) |
Half of the horizontal seat adjustment |
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av |
(mm) |
Half of the vertical seat adjustment |
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B |
(mm) |
Minimum overall width of the tractor; |
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B6 |
(mm) |
Maximum outer width of the protective structure; |
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D |
(mm) |
Deflection of the structure at the point of impact (dynamic tests) or at the point of, and in line with, the load application (static tests); |
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D’ |
(mm) |
Deflection of the structure for the calculated energy required; |
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Ea |
(J) |
Strain energy absorbed at point when load is removed. Area contained within F-D curve; |
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Ei |
(J) |
Strain energy absorbed. Area under F-D curve; |
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E’i |
(J) |
Strain energy absorbed after additional loading following a crack or tear; |
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E’’i |
(J) |
Strain energy absorbed in overload test in the event of the load having been removed before starting this overload test. Area under F-D curve; |
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Eil |
(J) |
Energy input to be absorbed during longitudinal loading; |
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Eis |
(J) |
Energy input to be absorbed during side loading; |
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F |
(N) |
Static load force; |
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F’ |
(N) |
Loading force for calculated energy required, corresponding to E’i ; |
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F-D |
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Force/deflection diagram; |
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Fmax |
(N) |
Maximum static load force occurring during loading, with the exception of the overload; |
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Fv |
(N) |
Vertical crushing force; |
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H |
(mm) |
Falling height of the pendulum block (dynamic tests); |
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H’ |
(mm) |
Falling height of the pendulum block for additional test (dynamic tests); |
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I |
(kgm2) |
Tractor reference moment of inertia about the centre line of the rear wheels, whatever the mass of these rear wheels may be; |
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L |
(mm) |
Tractor reference wheelbase; |
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M |
(kg) |
Tractor reference mass during strength tests. |
2. Field of application
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2.1. |
This Annex shall is applicable to tractors having at least two axles for pneumatic tyred wheels or having tracks instead of wheels and having the following characteristics:
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2.2. |
It is recognised that there may be designs of tractors, for example, special forestry machines, such as forwarders and skidders, for which this Annex is not applicable. |
B1 STATIC TEST PROCEDURE
3. Rules and directions
3.1. Conditions for testing the strength of protective structures and of their attachment to tractors
3.1.1. General requirements
3.1.1.1. 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.
3.1.1.2. Test methods
Tests may be performed in accordance with the static procedure or the dynamic procedure (see Annex II). The two methods are deemed equivalent.
3.1.1.3. General rules governing preparation for tests
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3.1.1.3.1. |
The protective structure must conform to the series production specifications. It shall be attached in accordance with the manufacturer’s recommended method to one of the tractors for which it is designed. Note: A complete tractor is not required for the static strength test; however, the protective structure and parts of the tractor to which it is attached represent an operating installation, hereinafter referred to as ‘the assembly’. |
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3.1.1.3.2. |
For both the static test and the dynamic test the tractor as assembled (or the assembly) must be fitted with all series production components which may affect the strength of the protective structure or which may be necessary for the strength test. Components which may create a hazard in the clearance zone must also be fitted on the tractor (or the assembly) so that they may be examined to see whether the requirements of the Acceptance Conditions in 3.1.3 have been fulfilled. All components of the tractor or the protective structure including weather protective must be supplied or described on drawings. |
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3.1.1.3.3. |
For the strength tests, all panels and detachable non-structural components must be removed so that they may not contribute to the strengthening of the protective structure. |
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3.1.1.3.4. |
The track width must be adjusted so that the protective structure will, as far as possible, not be supported by the tyres or the tracks during the strength tests. If these tests are conducted in accordance with the static procedure, the wheels or tracks may be removed. |
3.1.2. Tests
3.1.2.1. Sequence of tests according to the Static Procedure
The sequence of tests, without prejudice to the additional tests mentioned in sections 3.2.1.6, and 3.2.1.7 is as follows:
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(1) |
loading at the rear of the structure (see 3.2.1.1); |
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(2) |
rear crushing test (see 3.2.1.4); |
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(3) |
loading at the front of the structure (see 3.2.1.2); |
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(4) |
loading at the side of the structure (see 3.2.1.3); |
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(5) |
crushing at the front of the structure (see 3.2.1.5). |
3.1.2.2. General requirements
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3.1.2.2.1. |
If, during the test, any part of the tractor restraining equipment breaks or moves, the test shall be restarted. |
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3.1.2.2.2. |
No repairs or adjustments of the tractor or protective structure may be carried out during the tests. |
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3.1.2.2.3. |
The tractor gear box shall be in neutral and the brakes off during the tests. |
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3.1.2.2.4. |
If the tractor is fitted with a suspension system between the tractor body and the wheels, it shall be blocked during the tests. |
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3.1.2.2.5. |
The side chosen for application of the first load on the rear of the structure shall be that which, in the opinion of the testing authorities, will result in the application of the series of loads under the most unfavourable conditions for the structure. The lateral load and the rear load shall be applied on both sides of the longitudinal median plane of the protective structure. The front load shall be applied on the same side of the longitudinal median plane of the protective structure as the lateral load. |
3.1.3. Acceptance conditions
3.1.3.1. A protective structure is regarded as having satisfied the strength requirements if it fulfils the following conditions:
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3.1.3.1.1. |
during static testing, at the point when the energy required is attained in each horizontal load test prescribed or in the overload test the force must be greater than 0,8 F; |
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3.1.3.1.2. |
if during the test, cracks or tears appear as a result of the application of the crushing force, an additional crushing test as defined in 3.2.1.7 must be performed immediately after the crushing test which caused these cracks or tears to appear; |
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3.1.3.1.3. |
during the tests other than the overload test, no part of the protective structure must enter the clearance zone as defined in 1.6; |
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3.1.3.1.4. |
during the tests other than the overload test, all parts of the clearance zone shall be secured by the structure, in accordance with 3.2.2.2; |
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3.1.3.1.5. |
during the tests the protective structure must not impose any constraints on the seat structure; |
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3.1.3.1.6. |
the elastic deflection, measured in accordance with 3.2.2.3 shall be less than 250 mm. |
3.1.3.2. 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.
3.1.4. [Not applicable]
3.1.5. Test apparatus and equipment
3.1.5.1. Static testing rig
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3.1.5.1.1. |
The static testing rig must be designed in such a way as to permit thrusts or loads to be applied to the protective structure. |
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3.1.5.1.2. |
Provision must be made so that the load can be uniformly distributed normal to the direction of loading and along a flange having a length of one of the exact multiples of 50 between 250 and 700 mm. The stiff beam shall have a vertical face dimension of 150 mm. The edges of the beam in contact with the protective structure shall be curved with a maximum radius of 50 mm. |
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3.1.5.1.3. |
The pad shall be capable of being adjusted to any angle in relation to the load direction, in order to be able to follow the angular variations of the structure’s load-bearing surface as the structure deflects. |
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3.1.5.1.4. |
Direction of the force (deviation from horizontal and vertical):
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3.1.5.1.5. |
The deflection rate shall be sufficiently slow, less than 5 mm/s so that the load may at all moments be considered as static. |
3.1.5.2. Apparatus for measuring the energy absorbed by the structure
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3.1.5.2.1. |
The force versus deflection curve shall be plotted in order to determine the energy absorbed by the structure. There is no need to measure the force and deflection at the point where the load is applied to the structure; however, force and deflection shall be measured simultaneously and co-linearly. |
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3.1.5.2.2. |
The point of origin of deflection measurements shall be selected so as to take account only of the energy absorbed by the structure and/or by the deflection of certain parts of the tractor. The energy absorbed by the deflection and/or the slipping of the anchoring must be ignored. |
3.1.5.3. Means of anchoring the tractor to the ground
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3.1.5.3.1. |
Anchoring rails with the requisite track width and covering the necessary area for anchoring the tractor in all the cases illustrated must be rigidly attached to a non-yielding base near the testing rig. |
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3.1.5.3.2. |
The tractor must be anchored to the rails by any suitable means (plates, wedges, wire ropes, jacks, etc.) so that it cannot move during the tests. This requirement shall be checked during the test, by means of the usual devices for measuring length. If the tractor moves, the entire test shall be repeated, unless the system for measuring the deflections taken into account for plotting the force versus deflection curve is connected to the tractor. |
3.1.5.4. Crushing rig
A rig as shown in figure 7.3 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.
3.1.5.5. Other measuring apparatus
The following measuring devices are also needed:
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3.1.5.5.1. |
device for measuring the elastic deflection (the difference between the maximum momentary deflection and the permanent deflection, see figure 7.4). |
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3.1.5.5.2. |
device for checking that the protective structure has not entered the clearance zone and that the latter has remained within the structure’s protective during the test (section 3.2.2.2). |
3.2. Static test procedure
3.2.1. Loading and crushing tests
3.2.1.1. Loading at the rear
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3.2.1.1.1. |
The load shall be applied horizontally, in a vertical plane parallel to the tractor’s median plane. The load application point shall be that part of the roll-over protective structure likely to hit the ground first in a rearward overturning accident, normally the upper edge. The vertical plane in which the load is applied shall be located at a distance of 1/6 of the width of the top of the protective structure inwards from a vertical plane, parallel to the median plane of the tractor, touching the outside extremity of the top of the protective structure. If the structure is curved or protruding at this point, wedges enabling the load to be applied thereon shall be added, without thereby reinforcing the structure. |
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3.2.1.1.2. |
The assembly shall be lashed to the ground as described in 3.1.6.3. |
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3.2.1.1.3. |
The energy absorbed by the protective structure during the test shall be at least: or |
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3.2.1.1.4. |
For tractors with a reversible driver’s position (reversible seat and steering wheel), the energy shall be whichever is the higher of the formula selected above or the following: |
3.2.1.2. Loading at the front
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3.2.1.2.1. |
The load shall be applied horizontally in a vertical plane parallel to the tractor’s median plane. The point of application shall be that part of the protective structure likely to hit the ground first if the tractor overturns sideways while travelling forward, i.e. normally the upper edge. The point of application of the load shall be 1/6 of the width of the top of the protective structure inwards from a vertical plane parallel to the median plane of the tractor touching the outside extremity of the top of the protective structure. If the structure is curved or protruding at this point, wedges enabling the load to be applied thereon shall be added, without thereby reinforcing the structure. |
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3.2.1.2.2. |
The assembly shall be lashed to the ground as described in 3.1.6.3. |
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3.2.1.2.3. |
The energy absorbed by the protective structure during the test shall be at least: |
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3.2.1.2.4. |
In case of tractors with a reversible driver’s position (reversible seat and steering wheel):
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3.2.1.3. Loading from the side
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3.2.1.3.1. |
The side loading shall be applied horizontally, in a vertical plane perpendicular to the tractor’s median plane passing 60 mm in front of the Seat Index Point, the seat being at the mid position of the longitudinal adjustment. The load application point shall be that part of the roll-over protective structure likely to hit the ground first in a sideways overturning accident, normally the upper edge. |
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3.2.1.3.2. |
The assembly shall be lashed to the ground as described in 3.1.6.3. |
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3.2.1.3.3. |
The energy absorbed by the protective structure during the test shall be at least: |
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3.2.1.3.4. |
For tractors with a reversible driver’s position (reversible seat and steering wheel), the load application point shall be in the plane at right angles to the median plane and passing at the midpoint of the segment joining the two Seat Index Points defined by joining the two different positions of the seat. For protective structures having a two-post system, the load shall be located on one of the two posts. |
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3.2.1.3.5. |
In case of tractors with a reversible driver’s position (reversible seat and steering wheel) where the protective structure is a rear two-post rollbar, the energy shall be whichever is higher of the following: or |
3.2.1.4. 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 the 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.
3.2.1.5. 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.
3.2.1.6. Additional overload test (figures 7.5 to 7.7)
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 7.6).
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 7.7).
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 protective 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.
3.2.1.7. 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.
3.2.2. Measurements to be made
3.2.2.1. 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.
3.2.2.2. Entry into the clearance zone
During each test the protective structure shall be examined to see whether any part of it has entered a 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 is considered to be outside the protection of the roll-over protective structure if any part of it would have come in contact with the ground plane if the tractor had overturned in the direction from which the impact came. For this purpose the front and rear tyres and track setting are assumed to be the smallest specified by the manufacturer.
3.2.2.3. 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 7.4 may be used.
3.2.2.4. 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 used.
3.3. Extension to other tractor models
3.3.1. [Not applicable]
3.3.2. 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:
3.3.2.1. Extension of the structural test results to other models of tractors
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 3.3.2.1.1 to 3.3.2.1.5.
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3.3.2.1.1. |
The structure shall be identical to the one tested; |
|
3.3.2.1.2. |
The required energy shall not exceed the energy calculated for the original test by more than 5 per cent; the 5 % limit shall also apply to extensions in the case of substituting tracks for wheels on the same tractor; |
|
3.3.2.1.3. |
The method of attachment and the tractor components to which the attachment is made shall be identical; |
|
3.3.2.1.4. |
Any components such as mud-guards and bonnet that may provide support for the protective structure shall be identical; |
|
3.3.2.1.5. |
The position and critical dimensions of the seat in the protective structure and the relative position of the protective structure on the tractor shall be such that the clearance zone would have remained within the protection of the deflected structure throughout all tests (this shall be checked by using the same reference of clearance zone as in the original test report, respectively Seat Reference Point [SRP] or Seat Index Point [SIP]). |
3.3.2.2. Extension of the structural test results to modified models of the protective structure
This procedure has to be followed when the provisions of paragraph 3.3.2.1 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):
|
3.3.2.2.1. |
Modifications having no impact on the results of the initial test (e.g. weld attachment of the mounting plate of an accessory in a non-critical location on the structure), addition of seats with different SIP location in the protective structure (subject to checking that the new clearance zone(s) remain(s) within the protection of the deflected structure throughout all tests). |
|
3.3.2.2.2. |
Modifications having a possible impact on the results of the original test without calling into question the acceptability of the protective structure (e.g. modification of a structural component, modification of the method of attachment of the protective structure to the tractor). A validation test can be carried out and the test results will be drafted in the extension report. The following limits for this type extension are fixed:
|
|
3.3.2.2.3. |
Increase of the reference mass declared by the manufacturer for a protective structure already tested. If the manufacturer wants to keep the same approval number it is possible to issue an extension report after having carried out a validation test (the limits of ± 7 % specified in 3.3.2.2.2.2 are not applicable in such a case). |
3.4. [Not applicable]
3.5. Cold weather performance of protective structures
3.5.1. 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.
3.5.2. 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.
3.5.2.1. 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.
3.5.2.2. All welding electrodes used in the fabrication of structural members and mounts shall be compatible with the protective structure material as given in 3.5.2.3 below.
3.5.2.3. 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 7.1. 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.
3.5.2.4. 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 7.1 that the material will permit.
3.5.2.5. 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 7.1
Minimum Charpy V-notch impact energies
|
Specimen size |
Energy at |
Energy at |
|
|
– 30 °C |
– 20 °C |
|
mm |
J |
J (2) |
|
10 × 10 (1) |
11 |
27,5 |
|
10 × 9 |
10 |
25 |
|
10 × 8 |
9,5 |
24 |
|
10 × 7,5 (1) |
9,5 |
24 |
|
10 × 7 |
9 |
22,5 |
|
10 × 6,7 |
8,5 |
21 |
|
10 × 6 |
8 |
20 |
|
10 × 5 (1) |
7,5 |
19 |
|
10 × 4 |
7 |
17,5 |
|
10 × 3,5 |
6 |
15 |
|
10 × 3 |
6 |
15 |
|
10 × 2,5 (1) |
5,5 |
14 |
3.5.2.6. 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.
3.5.2.7. 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.
3.6. [Not applicable]
Figure 7.1
Clearance zone
Dimensions in mm
|
Figure 7.1.a Side view Section in reference plan |
Figure 7.1.b Rear view |
Figure 7.1.c
Seen from above
1– Seat index point
2– Reference plane
Figure 7.2.a
Clearance zone for tractors with reversible seat position: two-post rollbar
Figure 7.2.b
Clearance zone for tractors with reversible seat position: other types of ROPS
Figure 7.3
Example of crushing rig of the tractor
Figure 7.4
Example of apparatus for measuring elastic deflection
1– Permanent deflection
2– Elastic deflection
3– Total deflection (permanent plus elastic)
Figure 7.5
Force/deflection curve
Overload test not necessary
Notes:
|
1. |
Locate Fa in relation to 0,95 D’ |
|
2. |
Overload test not necessary as Fa ≤ 1,03 F’ |
Figure 7.6
Force / deflection curve
Overload test necessary
Notes:
|
1. |
Locate Fa in relation to 0,95 D’ |
|
2. |
Overload test necessary as Fa > 1,03 F’ |
|
3. |
Overload test performance satisfactory as Fb > 0,97 F’ and Fb > 0,8 Fmax. |
Figure 7.7
Force/deflection curve
Overload test to be continued
Notes:
|
1. |
Locate Fa in relation to 0,95 D’ |
|
2. |
Overload test necessary as Fa > 1,03 F’ |
|
3. |
Fb < 0,97 F’ therefore further overload necessary |
|
4. |
Fc < 0,97 Fb therefore further overload necessary |
|
5. |
Fd < 0,97 Fc therefore further overload necessary |
|
6. |
Overload test performance satisfactory, if Fe > 0,8 Fmax |
|
7. |
Failure at any stage when load drops below 0,8 Fmax. |
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. Conditions for testing the strength of protective structures and of their attachment to tractors
4.1.1. General requirements
See requirements stated for static testing in section B1
4.1.2. Tests
4.1.2.1. Sequence of tests according to the Dynamic Procedure
The sequence of tests, without prejudice to the additional tests mentioned in sections 4.2.1.6 and 4.2.1.7 is as follows:
|
(1) |
impact at the rear of the structure (see 4.2.1.1); |
|
(2) |
rear crushing test (see 4.2.1.4); |
|
(3) |
impact at the front of the structure (see 4.2.1.2); |
|
(4) |
impact at the side of the structure (see 4.2.1.3); |
|
(5) |
crushing at the front of the structure (see 4.2.1.5). |
4.1.2.2. General requirements
| |
4.1.2.2.1. |
If, during the test, any part of the tractor restraining equipment breaks or moves, the test shall be restarted. |
| |
4.1.2.2.2. |
No repairs or adjustments of the tractor or protective structure may be carried out during the tests. |
| |
4.1.2.2.3. |
The tractor gear box shall be in neutral and the brakes off during the tests. |
| |
4.1.2.2.4. |
If the tractor is fitted with a suspension system between the tractor body and the wheels, it shall be blocked during the tests. |
| |
4.1.2.2.5. |
The side chosen for application of the first impact on the rear of the structure shall be that which, in the opinion of the testing authorities, will result in the application of the series of impacts or loads under the most unfavourable conditions for the structure. The lateral impact and the rear impact shall be applied on both sides of the longitudinal median plane of the protective structure. The front impact shall be applied on the same side of the longitudinal median plane of the protective structure as the lateral impact. |
4.1.3. Acceptance conditions
4.1.3.1. A protective structure is regarded as having satisfied the strength requirements if it fulfils the following conditions:
|
4.1.3.1.1. |
after each test it shall be free from tears or cracks, as defined in 4.2.1.2.1. If significant tears or cracks appear during the test, an additional impact test or crushing test as defined in 4.2.1.6 or 4.2.1.7 must be performed immediately after the test which caused these tears or cracks to appear; |
|
4.1.3.1.2. |
during the tests other than the overload test, no part of the protective structure must enter the clearance zone as defined in 1.6; |
|
4.1.3.1.3. |
during the tests other than the overload test, all parts of the clearance zone shall be secured by the structure, in accordance with 4.2.2.2; |
|
4.1.3.1.4. |
during the tests the protective structure must not impose any constraints on the seat structure; |
|
4.1.3.1.5. |
the elastic deflection, measured in accordance with 4.2.2.3 shall be less than 250 mm. |
4.1.3.2. 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.
4.1.4. [Not applicable]
4.1.5. Apparatus and equipment for dynamic tests
4.1.5.1. Pendulum block
| |
4.1.5.1.1. |
A block acting as a pendulum must be suspended by two chains or wire ropes from pivot points not less than 6 m above the ground. Means must be provided for adjusting independently the suspended height of the block and the angle between the block and the supporting chains or wire ropes. |
| |
4.1.5.1.2. |
The mass of the pendulum block must be 2 000 ± 20 kg excluding the mass of the chains or wire ropes which themselves must not exceed 100 kg. The length of the sides of the impact face must be 680 ± 20 mm (see figure 7.18). The block must be filled in such a way that the position of its centre of gravity is constant and coincides with the geometrical centre of the parallelepiped. |
| |
4.1.5.1.3. |
The parallelepiped must be connected to the system which pulls it backwards by an instantaneous release mechanism which is so designed and located as to enable the pendulum block to be released without causing the parallelepiped to oscillate about its horizontal axis perpendicular to the pendulum’s plane of oscillation. |
4.1.5.2. Pendulum supports
The pendulum pivot points must be rigidly fixed so that their displacement in any direction does not exceed 1 per cent of the height of fall.
4.1.5.3. Lashings
| |
4.1.5.3.1. |
Anchoring rails with the requisite track width and covering the necessary area for lashing the tractor in all the cases illustrated (see figures 7.19, 7.20 and 7.21) must be rigidly attached to a non-yielding base beneath the pendulum. |
| |
4.1.5.3.2. |
The tractor shall be lashed to the rails by means of wire rope with round strand, fibre core, construction 6 × 19 in accordance with ISO 2408:2004 and a nominal diameter of 13 mm. The metal strands must have an ultimate tensile strength of 1 770 MPa. |
| |
4.1.5.3.3. |
The central pivot of an articulated tractor shall be supported and lashed down as appropriate for all tests. For the lateral impact test, the pivot shall also be propped from the side opposite the impact. The front and rear wheels or tracks need not be in line if this facilitates the attachment of the wire ropes in the appropriate manner. |
4.1.5.4. Wheel prop and beam
| |
4.1.5.4.1. |
A softwood beam of 150 mm square shall be used as a prop for the wheels during the impact tests (see figures 7.19, 7.20 and 7.21). |
| |
4.1.5.4.2. |
During the lateral impact tests, a softwood beam shall be clamped to the floor to brace the rim of the wheel opposite the side of impact (see figure 7.21). |
4.1.5.5. Props and lashings for articulated tractors
| |
4.1.5.5.1. |
Additional props and lashings must be used for articulated tractors. Their purpose is to ensure that the section of the tractor on which the protective structure is fitted is as rigid as that of a non-articulated tractor. |
| |
4.1.5.5.2. |
Additional specific details are given in section 4.2.1 for the impact and crushing tests. |
4.1.5.6. Tyre pressures and deflections
| |
4.1.5.6.1. |
The tractor tyres shall not be liquid-ballasted and shall be inflated to the pressures prescribed by the tractor manufacturer for field work. |
| |
4.1.5.6.2. |
The lashings shall be tensioned in each particular case such that the tyres undergo a deflection equal to 12 per cent of the tyre wall height (distance between the ground and the lowest point of the rim) before tensioning. |
4.1.5.7. Crushing rig
A rig as shown in figure 7.3 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 shall be provided so that the tractor tyres do not bear the crushing force.
4.1.5.8. Measuring apparatus
The following measuring apparatus is needed:
|
4.1.5.8.1. |
device for measuring the elastic deflection (the difference between the maximum momentary deflection and the permanent deflection, see figure 7.4). |
|
4.1.5.8.2. |
device for checking that the protective structure has not entered the clearance zone and that the latter has remained within the structure’s protective during the test (see section 4.2.2.2). |
4.2. Dynamic test procedure
4.2.1. Impact and crushing tests
4.2.1.1. Impact at the rear
| |
4.2.1.1.1. |
The tractor shall be so placed in relation to the pendulum block that the block will strike the protective structure when the impact face of the block and the supporting chains or wire ropes are at an angle with the vertical plane A equal to M/100 with a 20° maximum, unless, during deflection, the protective structure at the point of contact forms a greater angle to the vertical. In this case the impact face of the block shall be adjusted by means of an additional support so that it is parallel to the protective structure at the point of impact at the moment of maximum deflection, the supporting chains or wire ropes remaining at the angle defined above. The suspended height of the block shall be adjusted and necessary steps taken so as to prevent the block from turning about the point of impact. The point of impact is that part of the protective structure likely to hit the ground first in a rearward overturning accident, normally the upper edge. The position of the centre of gravity of the block is 1/6 of the width of the top of the protective structure inwards from a vertical plane parallel to the median plane of the tractor touching the outside extremity of the top of the protective structure. If the structure is curved or protruding at this point, wedges enabling the impact to be applied thereon must be added, without thereby reinforcing the structure. |
| |
4.2.1.1.2. |
The tractor must be lashed to the ground by means of four wire ropes, one at each end of both axles, arranged as indicated in figure 7.19. The spacing between the front and rear lashing points must be such that the wire ropes make an angle of less than 30° with the ground. The rear lashings must in addition be so arranged that the point of convergence of the two wire ropes is located in the vertical plane in which the centre of gravity of the pendulum block travels. The wire ropes must be tensioned so that the tyres undergo the deflections given in 4.1.5.6.2. With the wire ropes tensioned, the wedging beam shall be placed in front of and tight against the rear wheels and then fixed to the ground. |
| |
4.2.1.1.3. |
If the tractor is of the articulated type, the point of articulation shall, in addition, be supported by a wooden block at least 100 mm square and firmly lashed to the ground. |
| |
4.2.1.1.4. |
The pendulum block shall be pulled back so that the height of its centre of gravity above that at the point of impact is given by one of the following two formulae: or The pendulum block is then released and strikes the protective structure. |
| |
4.2.1.1.5. |
For tractors with a reversible driver’s position (reversible seat and steering wheel), the height shall be whichever is greater of either of the above or either of the following: for tractor with a reference mass of less than 2 000 kg; for tractor with a reference mass of more than 2 000 kg. |
4.2.1.2. Impact at the front
| |
4.2.1.2.1. |
The tractor shall be so placed in relation to the pendulum block that the block will strike the protective structure when the impact face of the block and the supporting chains or wire ropes are at an angle with the vertical plane A equal to M/100 with a 20° maximum, unless, during deflection, the protective structure at the point of contact forms a greater angle to the vertical. In this case the impact face of the block shall be adjusted by means of an additional support so that it is parallel to the protective structure at the point of impact at the moment of maximum deflection, the supporting chains or wire ropes remaining at the angle defined above. The suspended height of the pendulum block shall be adjusted and the necessary steps taken so as to prevent the block from turning about the point of impact. The point of impact is that part of the protective structure likely to hit the ground first if the tractor overturned sideways while travelling forward, normally the upper edge. The position of the centre of gravity of the block is 1/6 of the width of the top of the protective structure inwards from a vertical plane parallel to the median plane of the tractor touching the outside extremity of the top of the protective structure. If the structure is curved or protruding at this point, wedges enabling the impact to be applied thereon must be added, without thereby reinforcing the structure. |
| |
4.2.1.2.2. |
The tractor must be lashed to the ground by means of four wire ropes, one at each end of both axles, arranged as indicated in figure 7.20. The spacing between the front and rear lashing points must be such that the wire ropes make an angle of less than 30° with the ground. The rear lashings must in addition be so arranged that the point of convergence of the two wire ropes is located in the vertical plane in which the centre of gravity of the pendulum block travels. The wire ropes must be tensioned so that the tyres undergo the deflections given in 4.1.5.6.2. With the wire ropes tensioned, the wedging beam shall be placed behind and tight against the rear wheels and then fixed to the ground. |
| |
4.2.1.2.3. |
If the tractor is of the articulated type, the point of articulation shall, in addition, be supported by a wooden block at least 100 mm square and firmly lashed to the ground. |
| |
4.2.1.2.4. |
The pendulum block shall be pulled back so that the height of its centre of gravity above that at the point of impact is given by one of the following two formulae, to be chosen according to the reference mass of the assembly subjected to the tests: for tractor with a reference mass of less than 2 000 kg; for tractor with a reference mass of more than 2 000 kg. The pendulum block is then released and strikes the protective structure. |
| |
4.2.1.2.5. |
In case of tractors with a reversible driver’s position (reversible seat and steering wheel):
|
4.2.1.3. Impact from the side
| |
4.2.1.3.1. |
The tractor shall be so placed in relation to the pendulum block that the block will strike the protective structure when the impact face of the block and the supporting chains or wire ropes are vertical unless, during deflection, the protective structure at the point of contact forms an angle of less than 20° to the vertical. In this case the impact face of the block shall be adjusted by means of an additional support so that it is parallel to the protective structure at the point of impact at the moment of maximum deflection, the supporting chains or wire ropes remaining vertical on impact. |
| |
4.2.1.3.2. |
The suspended height of the pendulum block shall be adjusted and necessary steps taken so as to prevent the block from turning about the point of impact. |
| |
4.2.1.3.3. |
The point of impact shall be that part of the protective structure likely to hit the ground first in a sideways overturning accident, normally the upper edge. Unless it is certain that another part of this edge would hit ground first, the point of impact shall be in the plane at right angles to the median plane and passing 60 mm in front of the Seat Index Point, the seat being set at the mid position of longitudinal adjustment. |
| |
4.2.1.3.4. |
For tractors with a reversible driver’s position (reversible seat and steering wheel), the point of impact shall be in the plane at right angles to the median plane and passing at the midpoint of the segment joining the two Seat Index Points defined by joining the two different positions of the seat. For protective structures having a two-post system, the impact shall be located on one of the two posts. |
| |
4.2.1.3.5. |
The tractor wheels on the side which is to receive the impact must be lashed to the ground by means of wire ropes passing over the corresponding ends of the front and rear axles. The wire ropes must be tensioned to produce the tyre deflection values given in 4.1.5.6.2. With the wire ropes tensioned, the wedging beam shall be placed on the ground, pushed tight against the tyres on the side opposite that which is to receive the impact and then fixed to the ground. It may be necessary to use two beams or wedges if the outer sides of the front and rear tyres are not in the same vertical plane. The prop shall then be placed as indicated in figure 7.21 against the rim of the most heavily loaded wheel opposite to the point of impact, pushed firmly against the rim and then fixed at its base. The length of the prop shall be such that it makes an angle of 30° ± 3° with the ground when in position against the rim. In addition, its thickness shall, if possible, be between 20 and 25 times less than its length and between 2 and 3 times less than its width. The props shall be shaped at both ends as shown in the details on figure 7.21. |
| |
4.2.1.3.6. |
If the tractor is of the articulated type, the point of articulation shall in addition be supported by a wooden block at least 100 mm square and laterally supported by a device similar to the prop pushed against the rear wheel as in 4.2.1.3.5. The point of articulation shall then be lashed firmly to the ground. |
| |
4.2.1.3.7. |
The pendulum block shall be pulled back so that the height of its centre of gravity above that at the point of impact is given by one of the following two formulae, to be chosen according to the reference mass of the assembly subjected to the tests: for tractors with a reference mass of less than 2 000 kg; for tractors with a reference mass of more than 2 000 kg. |
| |
4.2.1.3.8. |
In case of tractors with a reversible driver’s position (reversible seat and steering wheel):
|
4.2.1.4. Crushing at the rear
All provisions are identical to those given in point 3.2.1.4 of section B1 to this Annex.
4.2.1.5. Crushing at the front
All provisions are identical to those given in section 3.2.1.5 of section B1 to this Annex.
4.2.1.6. Additional impact tests
If cracks or tears which cannot be considered negligible appear during an impact test, a second, similar test, but with a height of fall of:
shall be performed immediately after the impact tests causing these tears or cracks to appear, ‘a’ being the ratio of the permanent deformation (Dp) to the elastic deformation (De):
as measured at the point of impact. The additional permanent deformation due to the second impact shall not exceed 30 per cent of the permanent deformation due to the first impact.
In order to be able to carry out the additional test, it is necessary to measure the elastic deformation during all the impact tests.
4.2.1.7. Additional crushing tests
If during a crushing test, significant cracks or tears appear, a second, similar, crushing test, but with a force equal to 1,2 Fv shall be performed immediately after the crushing tests which caused these tears or cracks to appear.
4.2.2. Measurements to be made
4.2.2.1. Fractures and cracks
After each test all structural members, joints and fastening systems shall be visually examined for fractures or cracks, any small cracks in unimportant parts being ignored.
Any tears caused by the edges of the pendulum weight are to be ignored.
4.2.2.2. Entry into the clearance zone
During each test the protective structure shall be examined to see whether any part it has entered a clearance zone round the driving seat as defined in 1.6.
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.
4.2.2.3. Elastic deflection (under side impact)
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 7.4 may be used.
4.2.2.4. 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 used.
4.3. Extension to other tractor models
All provisions are identical to those given in section 3.3 of section B1 to this Annex.
4.4. [Not applicable]
4.5. Cold weather performance of protective structures
All provisions are identical to those given in section 3.5 of section B1 to this Annex.
Figure 7.18
Pendulum block and its suspending chains or wire ropes
Figure 7.19
Example of tractor lashing (rear impact)
Figure 7.20
Example of tractor lashing (front impact)
Figure 7.21
Example of tractor lashing (side impact)
Explanatory notes to Annex X
|
(1) |
Unless the numbering of section B2 which has been harmonised with the whole Annex, 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 rear mounted roll-over protective structures on narrow-track wheeled agricultural and forestry tractors, OECD Code 7, Edition 2015 of July 2014. |
|
(2) |
Users are reminded that the seat index point is determined according to ISO 5353:1995 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) |
Permanent + elastic deflection measured at the point when the required energy level is obtained. |
(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.