DE10301910B3 - Frame for supporting automobile drive train has bearing points for main mass provided by main transverse carrier offset in vertical and longitudinal directions from transverse carrier mountings - Google Patents

Abstract

The frame (1) has at least 2 transverse carriers (2,3,5,6) coupled together via a longitudinal carrier (4), providing a mounting plane (9) for the main mass (M) supported within the frame via 3 bearing points (A,B,C), the transverse carriers provided with mountings (D1,D2,D3,D4) for attaching the frame to an automobile chassis. Two of the bearing points are provided by the main transverse carrier and offset from the line between the mounting points for the latter in both the vertical and longitudinal directions, the third bearing point lying between the 2 longitudinal carrier elements (7,8) of the longitudinal carrier.

Description

The invention relates to a frame in detail with the features from the preamble of the claim 1.

Frames are known in a variety of designs for a wide variety of applications. In drive trains of vehicles in particular, these are of particular importance for supporting the forces caused by the operation of the components of the drive train. This applies in particular to the main mass of the drive train, which is generally formed by a drive machine, which is preferably in the form of an internal combustion engine, and possibly a gear unit, which forms a structural unit in the form of a motor / gear unit with the drive machine. It is desirable to direct the forces as directly as possible into the supporting elements of the frame so that it is not subjected to any deformations. The print is representative of this DE 100 61 127 A1 referenced, from which a frame concept for mounting components of the drive train of rail vehicles is known, which comprises at least two cross members, which are connected to form a mounting and arrangement level for the subframe via a longitudinal member.

The invention is therefore the object to develop a framework that allows the are optimally supported by the forces to be stored due to the main mass to be stored. This solution should be characterized by a low design effort. Furthermore, unwanted Deformation of the frame if possible be avoided.

The solution according to the invention is characterized by the features of claim 1 characterized. Advantageous configurations are reproduced in the subclaims.

According to the invention, the main mass is stored directly on the frame, which is supported by three bearing points. Two of the bearing points - a first and a second - are arranged on the main cross member, while the third is arranged in the connection between the side member elements of a side member connecting the cross members, according to a particularly advantageous embodiment in the center. Bearings for articulation on the vehicle or a stationary component are assigned to the frame, in particular the individual cross members, for example to the car body when used in rail vehicles. In order to avoid deformation of the frame when introducing and supporting the forces on the car body caused by the main mass to be stored, an eccentricity is established between the theoretical connecting axis of the bearing points of the main cross member and each of the two bearing points of the main mass, in particular the load introduction points defined on the main cross member in the vertical direction in a range of 0 ≤ e _Z ≤ 40% hm, where hm is the vertical height distance between the stored main mass and the respective bearing point in the main cross member and in the longitudinal direction in a range of 0 ≤ e _x ≤ 10 x _MAX , where x _{MAX is} the longitudinal distance represents between the bearing axles of the main and secondary cross member. The theoretical connecting axis between the bearings of the main cross member and the bearing points for the main mass on the main cross member preferably run parallel. Preferably, an eccentricity of 0 is also selected taking into account the tolerances caused by production and assembly, ie the load transfer axis defined by the connection axis of the bearing points of the main mass on the main cross member coincides with the connection axis of the bearings of the main cross member. This procedure allows a reduction of the moments introduced into the main cross member due to longitudinal and vertical loads. Since the center of gravity of the main mass is usually closer to the bearing points on the main cross member, the main proportion of the vertical load is introduced into the main cross member in accordance with the leverage ratios. The size of the torsional moments to be introduced into the main cross member depends on the size of the lever arm. Analogously, this also applies to the load in the longitudinal direction. If, for example, there is a load in the longitudinal direction of the frame, the main load is taken over by the main cross member, since according to the invention this takes over the longitudinal load from the main mass M. In the opposite case, however, a load due to the twisting or bending of the car body, to which the frame is articulated via the bearings, does not lead to undefined loads in the frame structure. The body and drive unit, i.e. main mass M, are better decoupled from each other.

The statically determined storage of the Main mass in three storage locations also prevents the build-up of internal ones forces which lead to preload of the bearings and the frame structure.

The solution according to the invention is described below explained by figures. The following is shown in detail:

1 illustrates the basic principle of two-stage storage in a schematically simplified representation using a perspective view of a frame;

2 illustrated with a main cross carrier according to 1 the arrangement according to the invention of the bearings of the main mass on the main cross member;

3 illustrates a particularly advantageous connection of the third bearing of the main mass to a rocker articulated on the side member elements.

The 1 illustrates in a schematically simplified representation based on the basic structure of a frame 1 the basic principle of a two-stage storage concept for drive units. The frame 1 includes at least two cross members 2 and 3 to link the frame 1 when used in vehicles, for example on a car body, the cross member 2 and 3 via at least one side member 4 be connected to each other. The cross member 2 is the main cross member 5 executed while the cross member 3 the function of the secondary cross member 6 takes over. The main mass M to be stored, which is, for example, the prime mover or a unit consisting of prime mover and transmission, ie a motor transmission unit, is primarily in the frame 1 by means of elastic bearings precisely defined with regard to stiffness and damping in bearing points A, B and C and the entire frame 1 with the remaining units opposite the vehicle again in special so-called secondary bearings D1 to D4, each of which is the cross member 2 and 3 assigned. The secondary bearings D1 and D2 serve to support the main cross member 5 , for example on a car body when used in rail vehicles and thus indirectly the storage of the main mass M on this. The bearings D1 and D2 are preferably in the end regions E1 and E2 of the main cross member 5 assigned to this or store it. Analogously, this also applies to the secondary cross member 6 , Here, the two bearings D3 and D4 on the secondary side are also the outer dimensions of the secondary crossmember viewed transversely to the direction of travel in a bearing 6 assigned, that is to say the end regions E3 and E4. Are preferably on the main cross member for this purpose 5 and on the secondary cross member 6 Corresponding bearing bolts B1 and B2 for the main cross member and B3 and B4 for the secondary cross member 6 arranged, which are then fixed in the bearings D1 to D4. The bearing bolts B1 to B4 are positively and / or non-positively and / or cohesively with the corresponding cross member - main cross member 5 or secondary cross member 6 - connected or form a structural unit with this.

The side member 4 comprises at least two longitudinal beam elements 7 and 8th which extend parallel in the longitudinal direction of the frame 1, preferably parallel to the direction of travel axis when installed in the vehicle, and the connection between the main cross member 5 and the secondary cross member 6 serve, the articulation of the longitudinal beam elements 7 and 8th to the individual cross beams 2 and 3 each takes place symmetrically. The main cross member 5 serves to absorb and transmit the main load in all directions, while the secondary cross member 6 serves to absorb the supporting forces of the main mass M, in particular the motor gear unit, and the main portion of the mass forces from auxiliary or additional units. The side member 4 , especially the side members 7.8 are continuously formed in the longitudinal direction over their extension. Other designs in which the longitudinal member consists of a plurality of elements which are lined up in this direction and are releasably or non-releasably connected to one another are also conceivable. The side member elements 7 and 8th are bent in a defined manner and form an assembly and arrangement level 9 for the main mass M or for the articulation of a subframe 10 for storing the main mass M. The bend is designed such that the connection 11 and 12 of the side member 4 , in particular the longitudinal beam elements 7 and 8th with the main cross member 5 in the through the main cross member 5 and a vertical plane formed in the longitudinal direction thereto 13 he follows. The connection 11 respectively. 12 the longitudinal beam elements 7 and 8th with the main cross member 5 is preferably rigid. The connection of the assembly and arrangement level 9 to the secondary cross member 6 takes place with the interposition of support beams 15 and 16 , each one of the longitudinal beam elements 7 and 8th are assigned and the longitudinal beam elements 7 and 8th with the secondary cross member 6 connect. The connection is preferably elastic, so that here an adapted elastic connection between the longitudinal beams 4 and secondary cross member 6 is possible. This can be in the connection between the longitudinal beam elements 7 and 8th and the support beams 15 and 16 with simultaneous rigid connection of the support beams 15 respectively 16 to the secondary cross member 6 or by rigid connection of the side member elements 7 and 8th to the support beams 15 and 16 and elastic connection of the support beams 15 and 16 to the secondary cross member 6 respectively. In the present case, the connections are 17 and 18 between support beam and longitudinal beam elements 7 and 8th made elastic. With this solution, the individual secondary suspension points of the frame 1 forming supporting frame is not directly connected, so quasi supported. As a result of the bending of the side member 4 a bending deformation can take place over its entire free length, which is accordingly at least on the span between the main and secondary cross members 5 respectively 6 acts. The result is a decoupling of the load and the forces between the main and secondary cross members 5 and 6 achieved because the necessary storage path for the transmission of force through the flexible side member elements 7 and 8th is partially taken over and compensated for. For example, there is a load in the longitudinal direction of the frame 1 , becomes the main load from the main cross member 5 taken over, since this takes over the longitudinal load from the main mass M according to the invention. In the opposite case, however, a load due to the twisting or bending of the car body does not lead to undefined loads in the frame structure, which is ultimately stored in the secondary bearings D1, D2 and D3, D4 in a statically undetermined manner. The body and drive unit, i.e. main mass M, are better decoupled from each other.

The main mass M, which is formed, for example, by a motor-gear unit, is stored according to the invention at three points. These are labeled A, B and C and define so-called load introduction points. A and B define the load instructions in the main beam. Since the center of gravity of the mass M to be stored is close to the connecting axis between the bearing points A and B, the main proportion of the vertical load in the main cross member becomes in accordance with the lever ratios 5 initiated. It makes sense that the eccentricity of these bearing points A and B in the longitudinal direction, which is defined by the dimension e _x , to the theoretical connecting axis A _{D1 – D2} and thus the bearing pin B1 and B2 is as small as possible, so that none via the lever arm Moments as torsional moments in the beam, i.e. in the main cross beam 5 be initiated, the main cross member 5 and also unnecessarily burden the corresponding bearing or bearings D1 or D2. If there is a load in the longitudinal direction, i.e. in the direction of the vehicle's longitudinal axis when the support frame is installed in a vehicle, this means that these forces are optimally at the same height as the bearing bolts B1 and B2 in the main cross member 5 should be initiated. The eccentricity in the vertical direction between the load introduction points defined by the bearing points A and B or the theoretical connection axis A _A - _B between the two, which is also referred to as the load introduction axis, is designated here by e _Z. The ideal would be a coincidence of the load introduction axis A _A _ _B with the connection _axis A _D1D2 between D1 and D2.

This procedure is particularly advantageous because the torsional moments mentioned in the main beam do not extend over the longitudinal beam 4 , especially the side members 7 and 8th or additional special bearing elements must be supported, since the bearings D1 and D2 are articulated about the bearing axes. The bearing point C, in particular the load introduction point specified by this, defines the bearing on the motor side. Another fourth storage location would over-determine the entire storage system and can therefore be omitted. The arrangement of the bearing point C takes place in the middle area between the downwardly extending longitudinal beam elements 7 and 8th , This makes sense because the center of gravity of the main mass M is optimally supported. However, the loads created at bearing point C are via the side member elements 7 . 8th that on the secondary beam 6 viewed locally in the same area in the longitudinal direction via support beams 15 . 16 , are connected. If a cross-stiffening profile were used, the development of torsional moments would then be observed in the transition to the side member elements, i.e. mainly in the area of the welded joints of the connection between the cross connection between the two side member elements 7 and 8th that with here 19 is designated. Therefore, the transition is articulated according to the invention, so that only transverse forces can be introduced. The result is a so-called seesaw 20 , which describes the connection and in its central area, preferably in the middle between the two longitudinal beam elements 7 and 8th , which has bearing C and at the ends 21 and 22 on the side member elements 7 and 8th is stored. The property of flexibility at the ends 21 and 22 is either by the provision of appropriate rubber elements 23 and 24 , like in the 3 shown, reproduced, or can be implemented by bushings, clevises or other design measures depending on the specific application.

The 2 clarifies once again with a section of the frame 1 , in particular based on the representation of the main cross member 5 , the basic principle of the connection of the bearing points A and B according to the invention for the main mass M, which either directly in the frame 1 or via one in the frame 1 stored subframe 10 is supported. In the case shown, the load introduction points A specified by the bearing points A, B are by means of corresponding rubber bearings 25 and 26 that on the main cross member 5 are arranged, defined. The loading forces in the vertical and in the longitudinal direction are illustrated by means of an arrow and are denoted by F _V for the forces in the vertical direction and F _L for the force in the longitudinal direction. You can also see those on the main cross member 5 arranged bearing bolts B1 and B2, which are stored in corresponding bearings D1 and D2. The connecting axis between the bearing bolts B1 and B2, which is characterized by the connecting axis of the bearing points on the bearings D1 and D2 and which is denoted by A _D1-D2 , runs parallel in the vertical and longitudinal directions, but offset to the connecting axis A _A _ _B between the load introduction points A and B in the corresponding rubber bearings 25 and 26 , The dimension e _x illustrates the eccentricity in the longitudinal direction, that is to say the offset between the connecting axes A _D1-D2 and A _A _ _B in the longitudinal direction, that is to say in the direction of travel or parallel to the direction of travel axis. The eccentricity e _Z describes the possible misalignment of the connecting axes A _{D1 – D2} and A _A _ _B viewed in the vertical direction in the installed position. Both eccentricities are preferred wise 0. According to the application requirements, however, they are selected for optimal load-bearing behavior in the vertical direction in a range of 0 ≤ e _Z ≤ 40% hm and in the longitudinal direction in a range of 0 ≤ ex ≤ 10% x _MAX , where hm is the vertical height distance between stored mass, in particular main mass and the respective bearing point on the main carrier 5 represents and x _MAX the longitudinal distance between the bearing axes of the main and secondary cross member 5 . 6 characterized.

The 3 illustrates with the aid of a section from frame 1 in the area of the connection of the longitudinal beam elements 7 and 8th via support beams 15 and 16 to the secondary cross member 6 the arrangement of the load introduction point defined by the third bearing point C on the cross connection 19 which, according to a particularly advantageous embodiment, is articulated on the longitudinal beam elements 7 and 8th is articulated. The cross connection 19 is as a seesaw 20 executed and supported by appropriate rubber elements 23 and 24 on the side member elements 7 and 8th from. The third bearing point C is preferably arranged in the center here, but can also be located anywhere between the longitudinal beam elements 7 and 8th on the cross connection 19 to be ordered.

1

frame

2

crossbeam

3

crossbeam

4

longitudinal beams

5

Bolster

6

Besides crossmember

D1, D2, D3, D4

camp

E1, E2, E3, E4

end

B1, B2, B3, B4

bearing bolt

7

Rail element

8th

Rail element

9

Assembly- and / or arrangement level

10

subframe

11

connection

12

connection

13

level

15

support beam

16

support beam

17

connection between support beam and Rail element

18

connection between support beam and Rail element

19

cross connection

20

seesaw

21

end the seesaw

22

end the seesaw

23

rubber element

24

rubber element

25

Rubber bearing

26

Rubber bearing

M

bulk

F _V

force in the vertical direction

F _L

force longitudinal

A _D1-D2

connecting axis

A _{A – B}

connecting axis

Claims (19)

Frame ( 1 ) 1.1 with at least two cross beams ( 2 . 3 . 5 . 6 ) that have a side member ( 4 ) to form an assembly and / or arrangement level which is offset in the vertical direction with respect to the cross members ( 9 ) are connected to each other for the main mass (M); 1.2 the main mass (M) is primarily in the frame ( 1 ) stored; 1.3 with the cross beams ( 2 . 3 . 5 . 6 ) associated bearings (D1, D2, D3, D4), which serve to connect the frame to a stationary component, in particular a car body; characterized by the following features: 1.4 the main mass (M) is at three bearing points (A, B, C) in the frame ( 1 ) stored at least indirectly; 1.5 two bearing points (A, B) are on the main cross member ( 5 ) is arranged, a third bearing point (C) is between the two longitudinal beam elements ( 7 . 8th ) arranged; 1.6 the bearing points (A, B) of the main mass (M) on the main cross member ( 5 ) are parallel and with an eccentricity in the vertical direction (e _Z ) and in the longitudinal direction (ex) to the theoretical connecting axis (A _{D1 – D2} ) of the bearings (D1, D2) for the main cross member ( 5 ) arranged, 1.6.1 the amount of eccentricity (e _Z ) of the individual bearing point (A, B) in the vertical direction in a range of 0 ≤ e _Z ≤ 40% hm, with hm equal to the vertical height distance between the main mass (M) and the bearing point and 1.6.2 the amount of eccentricity (ex) of the individual bearing point (A, B) in the longitudinal direction is in a range of 0 ≤ e _x ≤ 10% x _MAX , with x _MAX equal to the distance between the x _MAX theoretical connecting axes (A _{D1 – D4} , A _{D3 – D4} ) the bearings (D1, D2, D3, D4) of the main cross member ( 5 ) and secondary cross member ( 6 ). Frame ( 1 ) according to claim 1, characterized in that the eccentricity in the vertical direction (e _Z ) is equal to 0. Frame ( 1 ) according to one of claims 1 or 2, characterized in that the eccentricity (e _x ) in the longitudinal direction is 0. Frame ( 1 ) according to one of claims 1 to 3, characterized in that the bearing point (C) centrally between the two longitudinal beam elements ( 7 . 8th ) of the side member ( 4 ) is arranged. Frame ( 19 ) according to one of claims 1 to 4, characterized in that the bearing points (A, B) for the main mass (M) on the main cross member ( 5 ) are arranged on a theoretical connecting axis A _A _ _B , which are parallel to the theoretical connecting axis (A _{D1 – D2} ) of the bearings (D1, D) for the main cross member ( 5 ) runs. Frame ( 1 ) according to one of claims 1 to 5, characterized in that the bearing point (C), viewed in the longitudinal direction, is arranged in a region which corresponds to the arrangement of the secondary cross member ( 6 ) corresponds, but offset to these in the vertical direction. Frame ( 1 ) according to one of claims 1 to 6, characterized in that the longitudinal beam elements ( 7 . 8th ) run continuously in one piece and form the assembly and / or arrangement level ( 9 ) for the main mass (M) are defined. Frame ( 1 ) according to one of claims 1 to 7, characterized in that the longitudinal beam elements ( 7 . 8th ) rigid on the main cross member ( 5 ) and elastic on the secondary cross member ( 6 ) are articulated. Frame ( 1 ) according to claim 8, characterized in that the by the longitudinal member elements ( 7 ) characterized assembly and / or arrangement level ( 9 ) via support beams ( 15 . 16 ) on the secondary cross member ( 6 ) is articulated. Frame ( 1 ) according to claim 9, characterized in that the articulation of the longitudinal beam elements ( 7 . 8th ) on the support beams ( 15 . 16 ) elastic and the articulation of the support beams ( 15 . 16 ) on the secondary cross member ( 6 ) is rigid. Frame ( 1 ) according to claim 9, characterized in that the articulation of the longitudinal beam elements ( 7 . 8th ) on the support beams ( 15 . 16 ) is rigid and the linkage of the support beams ( 15 . 16 ) on the secondary cross member ( 6 ) is elastic. Frame ( 1 ) according to one of claims 1 to 11, characterized in that the third bearing point (C) on an articulated on the longitudinal beam elements ( 7 . 8th ) mounted rocker is arranged. Frame ( 1 ) according to claim 12, characterized in that the rocker the longitudinal beam elements ( 7 . 8th ) connects in the transverse direction. Frame ( 1 ) according to one of claims 12 or 13, characterized in that the function of the articulated mounting between rocker and side member elements ( 7 . 8th ) is taken over by rubber bearings arranged between them. Frame ( 1 ) according to one of claims 12 or 13, characterized in that the function of the articulated mounting between rocker and side member elements ( 7 . 8th ) one of the side member ( 7 . 8th ) at least with socket fitting enclosing and connected to the rocker socket. Frame ( 1 ) according to one of claims 12 or 13, characterized in that the function of the articulated mounting between rocker and side member elements ( 7 . 8th ) of one with one element - rocker or side member ( 7 . 8th ) connected fork head, which surrounds the other element - side member or rocker. Frame ( 1 ) according to one of claims 1 to 16, characterized in that the bearings (D1, D2, D3, D4) are designed as elastic bearings. Frame ( 1 ) according to one of claims 1 to 17, characterized in that the storage of the main mass (M) at the bearing points (A, B, C) takes place in bearings precisely defined with regard to rigidity and damping properties. Frame ( 1 ) according to claim 18, characterized in that the bearings as rubber-metal-La ger are trained.