EP0584323A1

EP0584323A1 - Lorry chassis

Info

Publication number: EP0584323A1
Application number: EP19930905280
Authority: EP
Inventors: Helmut Jun. Sinz
Original assignee: Individual
Current assignee: Individual
Priority date: 1992-02-28
Filing date: 1993-03-01
Publication date: 1994-03-02
Also published as: WO1993016908A1; DE4206271A1

Abstract

L'invention concerne un châssis de camion comportant un cadre de châssis (1), un essieu avant (3) pour des roues orientables (14) ainsi que deux essieux arrière (4, 5). Cette invention permet de réaliser un châssis d'un genre nouveau qui présente notamment des avantages pour les véhicules utilitaires communaux. Selon l'invention, le châssis de camion est caractérisé en ce qu'au moins les deux essieux arrière (4, 5) sont équipés de roues tractables (15, 16), en ce que l'essieu arrière (5) le plus à l'arrière est muni de roues orientables (15) et en ce qu'afin de reporter la charge du cadre de châssis (1) sur les essieux arrière (4, 5), il est prévu des deux côtés du cadre de châssis (1) une entretoise (17) s'étendant dans le sens longitudinal du châssis et articulée au niveau du cadre de châssis (1) dans un pivot (18) situé entre les deux essieux arrière (4, 5). Cette solution réalisée selon l'invention permet de satisfaire aux exigences formulées au niveau des véhicules utilitaires communaux, notamment en termes de maniabilité et d'aptitude tous-terrains.The invention relates to a truck chassis comprising a chassis frame (1), a front axle (3) for steerable wheels (14) and two rear axles (4, 5). This invention makes it possible to produce a chassis of a new kind which notably has advantages for municipal utility vehicles. According to the invention, the truck chassis is characterized in that at least the two rear axles (4, 5) are equipped with towable wheels (15, 16), in that the rear axle (5) the most the rear is provided with steerable wheels (15) and in that in order to transfer the load from the chassis frame (1) to the rear axles (4, 5), it is provided on both sides of the chassis frame (1 ) a spacer (17) extending in the longitudinal direction of the chassis and articulated at the level of the chassis frame (1) in a pivot (18) located between the two rear axles (4, 5). This solution produced according to the invention makes it possible to satisfy the requirements formulated in terms of municipal utility vehicles, in particular in terms of maneuverability and off-road ability.

Description

description

Truck chassis

The invention relates to a truck chassis, with a chassis frame, a front axle for steerable wheels and with two rear axles.

Commercial vehicles with special bodies, such as cleaning vehicles, fire engines, crane vehicles and the like, which are used primarily in the municipal area, are often subject to extremely high demands with regard to maneuverability and off-road capability. Such vehicles may have to can maneuver in very narrow alleys and on the other hand also to drive over large bumps and / or boggy terrain sections, e.g. Garbage dumps or construction sites.

The chassis of previously known commercial vehicles could not meet these different requirements to a satisfactory degree. In the case of the three-axle chassis designed to accommodate the necessary loads, tire erosion has so far been caused by erasing the rear wheels, or there were disadvantages if, in addition to steerable front wheels, non-driven steerable rear wheels were used to reduce the wear, the disadvantages that due to the Distribution of the load on two axles, the drive axle is only subjected to a lower load, which considerably reduces traction while the total load remains the same.

With the present invention, a new concept for a truck chassis is proposed, which different requirements to be met by municipal utility vehicles.

The truck chassis according to the invention is characterized in that at least the two rear axles are provided with drivable wheels, that the rear rear axle is provided with steerable wheels, and that for load transfer from the chassis frame to the rear axles on both sides of the chassis frame, one at a pivot point between vertical, through the two rear axles planes articulated on the chassis frame, extending in the chassis longitudinal direction intermediate support is provided.

With this solution according to the invention, increased maneuverability is achieved in that the wheelbase between the front wheels and the front rear wheels can be selected to be lower than that of a two-axle vehicle of the same load-bearing capacity, and in connection with the steerability of the wheels of the rear rear axle ^*, the turning radius solely by the wheelbase between the front wheels and the front rear wheels is determined. The use of the independently movable intermediate girders ensures an extremely high level of terrain maneuverability, since this ensures that all rear wheels, which are all driven, are in constant contact with the ground. On the other hand, there is an improvement in the ratio of payload to dead weight in that the floor load on individual wheels can be minimized by constant ground contact of all wheels, which is particularly advantageous for maneuverability on uneven, muddy soils.

In a preferred embodiment of the invention, a transfer case is provided, via which optionally also Front wheels are drivable. This all-wheel drive results in a further improvement in off-road capability.

In a further advantageous embodiment of the invention it can be provided that the fulcrum at which the intermediate supports are articulated on the chassis frame is provided according to a desired axle load distribution on the two rear axles outside the longitudinal center of the intermediate supports. In this way, an optimal axle load distribution can be set depending on the intended use of a vehicle using the truck chassis according to the invention.

Further advantageous design options of the invention emerge from the subclaims.

The invention will now be explained and described in more detail with reference to exemplary embodiments and the accompanying drawings relating to one of these exemplary embodiments. Show it:

Fig. 1 shows a truck chassis according to the invention in a side view, and

Fig. 2 shows the truck chassis according to the invention according to FIG. 1 in a plan view (without Fahrgesteilrah¬ men).

The one shown in Figs. 1 and 2

Truck chassis comprises a vehicle frame 1 on which a vehicle cab 2 is mounted. In the exemplary embodiment shown, the chassis frame 1 consists of two longitudinal beams which have a U-shaped profile and which face one another with the open sides of their U-shaped profile. The longitudinal beams are not in FIGS. 1 and 2 shown cross struts connected together. The reference numeral 6 denotes a transfer gear unit which is held on the chassis frame 1 and from which articulated drive shafts 7 and 8 extend to the rear axles and the front axle, respectively. The drive shaft 8 connects the transfer case 6 to a differential gear 9 attached to the front axle 3. The drive shaft 7 connects the transfer case 6 to a differential gear 10 attached to a first rear axle 4. The differential gear 10 on the first rear axle 4 is connected via a further drive shaft 11 connected to a differential gear 12, which is arranged on a second rear axle 5, which is provided behind the first rear axle 4.

With 14 are attached to the front axle 3 front wheels. The rear wheels attached to the rear axles 4 and 5 have the designations 15 and 16. The rear wheels 16 are each designed as double wheels comprising two rims and two tires. Both the front wheels

14 and the rear wheels 15 attached to the rear rear axle 5 can be steered via a schematically illustrated steering linkage 13. The steering linkage 13 is designed such that the turning of the front wheels 14 in a certain ratio to the turning of the rear rear wheels

15 stands. This ratio is determined by the distance between the front axle and the front rear axle to the distance between the front and the rear rear axle.

In FIG. 2, the axes 3, 4 and 5 designed as continuous rigid axes in the exemplary embodiment shown are only indicated by dash-dotted lines. Parts of the steering linkage 13 arranged between the steerable wheels 14 and 15 are not shown in FIGS. 1 and 2.

With 17 in Fig. 1 is at a pivot point 18 on Chassis frame 1 articulated intermediate support. The intermediate carrier, which in the exemplary embodiment shown has a U-shaped profile, engages around a longitudinal member of the chassis frame. At the pivot point 18, this side member, which, as already mentioned, has a U-profile, is reinforced to form a box section, so that a connecting bolt, which connects the intermediate member 17 to the chassis frame, is mounted twice on the side member in bores in side walls of the side member. An intermediate carrier corresponding to the intermediate carrier 17 and not visible in FIG. 1 is attached to the opposite side of the chassis frame in the manner described. The axes 4 and 5 are connected to the intermediate carrier 17 via leaf springs 19 and 20, the leaf springs being connected to the intermediate carrier 17 at articulation points 21 to 24. The front axle 3 is cushioned against the chassis frame 1 by means of leaf springs 25, the leaf springs 25 being attached to the chassis frame at articulation points 26 and 27.

When driving, in the embodiment shown for a truck chassis, it can be ensured via the transfer case 6 that a vehicle is driven only via the rear wheels or both via the rear wheels and the front wheels. The differential 6 could also be designed for the selection of a drive limited solely to the front wheels.

The route designated A in FIG. 2 corresponds to the wheelbase between the front wheels and the front rear wheels. In the exemplary embodiment shown, the wheelbase A is significantly smaller than it could be chosen for a two-axle vehicle with the same load-bearing capacity. Due to the fact that the wheels of the rear rear axle are steered, the wheelbase A corresponds to that Turning radius B of the vehicle, which is thus significantly reduced compared to a two-axle vehicle. Compared to a three-axle vehicle with rigid rear axles, there is also a smaller turning radius and at the same time the disadvantageous erasing is avoided. The resulting small turning radius makes the vehicle more manoeuvrable. The turning radius is indicated in FIG. 2 by the arrow labeled B. The load is transferred to the rear wheels via the intermediate carriers 17, which in turn are independent of one another so that the rear wheels on both sides of the chassis can independently follow one another while maintaining contact with the ground, thereby ensuring extremely high off-road mobility. The fact that all wheels keep contact with the ground also prevents individual wheels from being overloaded and ensures optimum traction through all wheels.

In the embodiment shown, the center of rotation is shifted 18 with respect to the longitudinal center of the ^{'intermediate} support 17 to the front, resulting in differently sized axle loads for the two rear axles 4 and 5 result. The pivot point 18 could, however, also be provided in the longitudinal center of the intermediate carrier 17 in accordance with a desired load distribution deviating from the uneven distribution. Instead of the shown direct arrangement of the second rear axle 5 behind the first rear axle 4, the second rear axle could also be attached further away from the first rear axle.

Contrary to the intermediate beams 17 shown, which are designed as a U-shaped profile, intermediate beams which are themselves formed by leaf springs would also be conceivable, which simplified the number of required components Construction would lead. Instead of the leaf springs shown, the use of coil springs could also be considered. Instead of holding the rear wheels on continuous rigid rear axles, a sprung attachment of the rear wheels to the intermediate supports, which can be moved independently of one another about the respective pivot point 18, could also be provided in the manner of an independent wheel suspension.

Claims

Truck chassis Patent claims:

1. truck chassis, with a chassis frame (1), a front axle (3) for steerable wheels (14) and with two rear axles (4, 5),

characterized,

that at least the two rear axles (4, 5) are provided with drivable wheels (15, 16),

that the rear rear axle (5) is provided with steerable wheels (15), and

that for load transfer from the chassis frame (1) to the rear axles (4, 5) on both sides of the chassis frame one in each case at a fulcrum (18) between vertical planes stepping through the two rear axles (4, 5) on the chassis frame, which

Intermediate carrier (17) extending in the longitudinal direction of the chassis is provided.

2. truck chassis according to claim 1, characterized in that the rear rear axle (5) is arranged directly behind the front rear axle (4).

3. truck chassis according to claim 1 or 2, characterized in that both the rear axles (4, 5) and the front axle (3) are provided with drivable wheels.

4. truck chassis according to one of claims 1 to

3, characterized in that the turning radius is equal to the wheelbase between the front axle (3) and the front rear axle (4).

5. truck chassis according to one of claims 1 to

4, characterized in that a steering device is provided for the simultaneous steering of the front and rear rear wheels in a predetermined steering angle ratio.

6. truck chassis according to claim 5, characterized in that the steering angle ratio corresponds to the ratio of the wheelbase between the front axle and the front rear axle to the wheelbase between the front and rear rear axles.

7. truck chassis according to one of claims 1 to

6, characterized in that the rear axles (4, 5) are cushioned against the intermediate supports (17) by leaf and / or coil springs.

8. truck chassis according to one of claims 1 to

7, characterized in that the intermediate carriers (17) themselves are formed by leaf springs.

9. truck chassis according to one of claims 1 to

8, characterized in that the intermediate carrier (17) have a U-profile.

10. truck chassis according to claim 9, characterized in that the U-profile comprises a side member of the chassis frame.

11. truck chassis according to one of claims 1 to

10, characterized in that the chassis frame (1) comprises longitudinal members with a U-profile.

12. truck chassis according to one of claims 1 to

11, characterized in that the chassis frame (l) comprises longitudinal beams which have a box section at least in a section containing the pivot point (18).

13. truck chassis according to one of claims l to

12, characterized in that the pivot point (18) for generating different rear axle loads is arranged outside the longitudinal center of the intermediate carrier (17).

14. Truck chassis according to one of claims l to

13, characterized in that rear wheels are attached to the intermediate carriers (17) in the manner of an independent wheel suspension.