KR100527784B1 - engine mounting system for automotive vehicles - Google Patents

Abstract

The present invention improves the ride performance of the vehicle by appropriately controlling the displacement of the engine generated while driving, and also improves the NVH performance of the vehicle by increasing the input point stiffness of the engine and the transmission side mounting parts and improving the vibration insulation rate. The aim is to improve the

In order to achieve the above object, the present invention, the engine mount unit 10 for supporting and connecting between the engine 1 and the side member 3 of the left and right body in the engine room, and the side member 3 and Transmission mount portion 20 for supporting and connecting between transmissions 5, and roll rod mount portion for supporting and connecting between engagement portion between engine 1 and transmission 5 and cross member 7 of the vehicle body. (30), the engine mount portion (10) is fixed to the upper and lower brackets (11, 12), the bridge type insulator (13) bonded to the lower bracket (12), and the insulator (13). Equipped with inner pipe 14; The transmission mount portion 20 includes an outer pipe 21, a bridge type insulator 22 joined to the outer pipe 21, and an inner pipe 23 fixed to the insulator 22. The rod mount unit 30 is characterized by consisting of a bush-type mount 31 located at both ends and a roll rod 32 connecting the bush-type mount 31.

Description

Engine mounting system for automotive vehicles

The present invention relates to an engine mounting system of an automobile, and more particularly, to improve the ride performance of the vehicle by appropriately controlling the displacement of the engine, and to increase the input point dynamics and the vibration insulation rate for each mounting portion. The present invention relates to an engine mounting system of a vehicle that enables to improve the vehicle's NVH performance.

In general, an engine mounting system for supporting an engine of a vehicle and isolating noise and vibration from the engine is largely divided into an inertial spindle type (three to four point support) and a center of gravity type (three point support).

In general, when considering weight and cost reduction aspects, such as light cars, the center of gravity method or the inertia spindle method (three-point support) is applied as an engine mounting system. In the case of the center of gravity method, a subframe is required or a cross member is used. Since the center member is required, recently, the inertial spindle three-point support system is mainly adopted to improve fuel efficiency due to weight reduction.

The three-point inertial engine mounting system is mounted on the body of the engine and transmission side mounting parts, and the roll mount or roll rod is mounted on the cross member. It is known to be advantageous in weight and the like compared to the supporting method.

In addition, the center of gravity three-point support method is difficult to control the roll of the engine because all the mounting parts are mounted on the lower part of the engine, and it is known that it is inferior to the three-point inertial spindle support method in NVH or RIDE performance. ought.

However, the inertial spindle three-point engine mounting system generally applied to small vehicles supports the engine with three mounts, one of which uses a lot of roll rods to control the roll displacement of the engine. The vertical displacement of the engine becomes relatively large.

Therefore, the ride performance of the vehicle is deteriorated, and in order to compensate for this, the fluid-mounted mount (hydro mount) may be applied to the engine mounting portion or the transmission mounting portion, respectively.

By the way, the fluid-mounted mount has a disadvantage in terms of weight compared to other mounts, especially in the case of a low-cost manufacturing car is an expensive part, it was inevitable in terms of cost.

Accordingly, the present invention has been made in view of the above, and by appropriately controlling the displacement of the engine generated during driving, improving the ride performance of the vehicle, and increasing the input point dynamics of each mounting portion of the engine and the transmission side. The purpose of the present invention is to improve the NVH performance of the vehicle by improving the vibration insulation rate.

The present invention for achieving the above object, the engine mount portion for supporting and connecting between the side member of the engine and the left and right body in the engine room, the transmission mount portion for supporting and connecting between the side member and the transmission; And a roll rod mount for supporting and connecting the coupling portion between the engine and the transmission and the cross member of the vehicle body, wherein the engine mount portion includes an upper / lower bracket and a bridge type insulator joined to the lower bracket, and the insulator Equipped with inner pipe fixed to it; The transmission mount portion has an outer pipe, a bridge type insulator joined to the outer pipe, and an inner pipe fixed to the insulator, and the roll rod mount portion connects between the bush mounts located at both ends and the bush mount. It is characterized by consisting of a roll rod.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

As shown in FIG. 1, the engine 1 and the transmission 5 are supported by three points on the side member 3 and the cross member 7 located at the rear of the left and right bodies, respectively, in the engine room. It is made of a structure.

Here, the engine mount unit 10 is positioned between the engine 1 and the right side member 3 of the vehicle body, and the transmission mount unit 20 is disposed between the transmission 5 and the left side member 3 of the vehicle body. The roll rod mount portion 30 is positioned between the engagement portion between the engine 1 and the transmission 5 and the cross member 7.

First, as shown in FIG. 2, the engine mount unit 10 is divided into upper and lower brackets, and upper and lower brackets 11 and 12 are joined to both front and lower ends, and the upper and lower brackets 11 and 12. A bridge type insulator 13 which is vulcanized and fixed between the brackets) and a support bracket assembly 14 for coupling the engine mount 10 to the right side member 3.

The center portion of the upper and lower brackets 11 and 12 in the engine mount 10 is a flat plate bent in a convex shape, respectively, as shown in (a) and (b) of FIG. 3. It is formed by, and the two front end portions located at each edge are joined to each other by spot welding.

The lower end of the bridge type insulator 13 is vulcanized and fixed to the lower bracket 12, and the inner pipe 15 is vulcanized and fixed to the central portion of the insulator, and the upper bracket 11 is the lower bracket. When coupled to 12, the bridged insulators 13 are joined together so as to be in a precompressed state.

The support bracket assembly 14 coupled to the right side member 3 has the engine mount portion 10 in the engine room via a bolt B (shown in FIG. 2) passing through the inner pipe 15. Is supported on the side member (3).

The bridge-type insulator 13 has a main buffer part in which an inner pipe 15 is mounted at the center and extended to be divided into a plurality of edge parts, and each end thereof is coupled to or adhered to the upper and lower brackets 11 and 12. 13a) and an auxiliary buffer portion 13b having a bottom surface coupled to the lower bracket 12 at a predetermined distance from the main buffer portion.

In the figure, reference numeral 16 denotes a mounting bracket for fixing the engine mount unit 10 to the engine 1.

Accordingly, the engine mount unit 10 having the structure as described above is fixed by vulcanizing and fixing the insulator 13 between the upper and lower brackets 11 and 12 with a preload. When the load generated according to the operation is transmitted, the insulator 13 is pre-shrunk due to the preload, thereby minimizing the displacement.

As a result, since the gap between the upper and lower brackets 11 and 12 and the insulator 13 is minimized, the large displacement behavior of the engine 1 can be effectively controlled, thereby improving the ride performance of the vehicle.

In addition, the engine mount unit 10 replaces a conventional fluid-filled engine mount that reduces the displacement by increasing the damping value at the time of large displacement of the engine 1 by applying the insulator 13 in a preloaded state. Since it can be made, it is advantageous in terms of cost.

In conclusion, the engine mount unit 10 can expect a similar effect to that actually applied without applying an expensive fluid-enclosed engine mount, that is, it can minimize the displacement itself, thereby improving the ride performance of the vehicle. will be.

4 and 5, the transmission mount unit 20 has a cylindrical outer pipe 21 and a bridge type insulator fixed by vulcanization and fixed to an inner circumferential surface of the outer pipe 21. 22) and an inner pipe 23 which is vulcanized and fixed to the central portion of the insulator, the inner pipe 23 being arranged in the left and right directions of the vehicle body.

The mounting bracket 24 coupled to the outside of the outer pipe 21 is coupled to be located at the top of the side member 3 in the engine compartment.

The bridge insulator 22 includes a main shock absorbing portion 22a having an inner pipe 23 mounted at the center thereof and extending to be divided into a plurality of edge portions, each of which has a front end coupled to the outer pipe 21. The auxiliary buffer part 22b having a bottom surface coupled to the outer pipe 21 at a predetermined distance from the main buffer part has a structure.

Reference numeral 25 in the figure is a mounting bracket for fixing the transmission mount portion 20 to the transmission (5).

A bolt B (shown in FIG. 4) penetrating the inner pipe 23 of the insulator 22 from the mounting bracket 25 is connected to the transmission member 20 with the side member 3 and the transmission 5. ) To connect and support.

Accordingly, the transmission mount portion 20 is formed by the main buffer portion 22a of the insulator 22 to form a compressive external force acting in the front-back direction of the bridge-type insulator 22 by the roll of the engine during acceleration. By accelerating the bridge portion, it is possible to reduce the acceleration transmission noise of the vehicle through the gradual change of the spring characteristic value.

In addition, the roll rod mount unit 30 serves to connect the coupling portion between the engine 1 and the transmission 5 and the cross member 7 of the vehicle body, that is, as shown in FIG. 6. And a bush rod 31 located at both ends and a roll rod 32 connecting the bush mount.

Each of the bush-type mounts 31 is a cylindrical outer pipe 31a, a bush-type insulator 32b fixedly vulcanized and fixed to an inner circumferential surface of the outer pipe, and vulcanically bonded to a central portion of the insulator An inner pipe 32c is provided. In particular, the installation direction of the inner pipe 32c in the bush-type mount 31 is selected in the left and right directions of the vehicle.

In the drawing, reference numeral 33 denotes a coupling portion between the engine 1 and the transmission 5 with the bush-shaped mount 31 positioned at both ends of the roll rod 32 in the roll rod mount unit 30. It is a mounting bracket for fixing to the cross member 7 of the vehicle body, respectively.

Accordingly, the roll rod mount unit 30 receives a compressive external force acting in the front-rear direction of the bush-type mount 31 by the roll of the engine upon acceleration so that the insulator 32b installed in the left and right directions of the vehicle receives the spring. The gradual change of the characteristic value can reduce the vehicle's accelerated transmission noise.

As described above, according to the engine mounting system of an automobile according to the present invention, the preload is applied to fix the engine 1 and the transmission 5 to the side member 3 and the cross member 7 in the engine compartment, respectively. By using the engine mount unit 10 in the state and the transmission mount unit 20 and the roll rod mount unit 30 provided in the left and right directions of the vehicle body, respectively, more effectively against the large displacement behavior generated by the operation of the engine 1. In addition, it is possible to more effectively cushion the load displacement acting in the front and rear direction of the vehicle body, thereby improving the ride performance of the vehicle.

In addition, since it is possible to replace the fluid-enclosed engine mount by applying a preload or by changing the installation direction using a conventional rubber engine mount, there is an advantage in terms of cost.

1 shows schematically an engine mounting system according to the invention.

2 and 3 are separated and shown only the engine mounting portion in FIG.

4 and 5 are separated and shown only the transmission mounting portion in FIG.

FIG. 6 is a view illustrating the rear roll rod mounting portion separately from FIG. 1; FIG.

<Description of Symbols for Main Parts of Drawings>

1-engine 3-side member

5-transmission 7-cross member

10-engine mount 11,12-top / bottom bracket

13-Insulator 14-Support Bracket Assembly

20-transmission mount 21-outer pipe

22-insulator 23-inner pipe

30-roll rod mount 31-bush mount

32-roll rod

Claims (3)

An engine mount 10 for supporting and connecting between the engine 1 and the side members 3 of the left and right bodies in the engine room, and a transmission supporting and connecting between the side members 3 and the transmission 5. In the engine mounting system of an automobile having a mount portion 20 and a roll rod mount portion 30 which supports and connects between the engagement portion between the engine 1 and the transmission 5 and the cross member 7 of the vehicle body. In The engine mount unit 10 includes upper and lower brackets 11 and 12 that are divided into upper and lower parts, a bridge type insulator 13 having a lower end joined to the lower bracket 12, and the insulator 13. An inner pipe (14) fixed to a central portion, the upper and lower brackets (11, 12) being mutually coupled to precompress the insulator (13); The transmission mount portion 20 includes an outer pipe 21, a bridge type insulator 22 joined to an inner circumferential surface of the outer pipe 21, and an inner pipe 23 fixed to a central portion of the insulator 22. Is provided, the inner pipe 23 is disposed in the left and right directions of the vehicle body; The roll rod mount portion 30 is composed of a bush-type mount 31 located at both ends and a roll rod 32 connecting the bush-type mount 31, the bush-type mount 31 is a vehicle body The engine mounting system of the vehicle, characterized in that arranged in the left and right directions. The insulator (13) of the engine mount (10) is extended to be divided into a plurality of edges with an inner pipe (15) mounted at the center thereof, so that each end of each of the front and lower brackets ( 11 and 12, and the main buffer portion 13a coupled to the surface and the auxiliary buffer portion 13b having a bottom surface coupled to the lower bracket 12 at a predetermined distance from the main buffer portion. Mounting system of the car. The insulator 22 of the transmission mount 20 has an inner pipe 23 mounted at the center thereof, and is extended to be divided into a plurality of edge portions. A main shock absorbing portion 22a coupled to or attached to the second shock absorber and an auxiliary shock absorbing portion 22b having a bottom surface coupled to the outer pipe 21 at a predetermined distance from the main shock absorbing portion. Mounting system.