KR101366107B1 - Flexible coupling with hydraulic vibration damper - Google Patents

Abstract

Disclosed herein is a flexible coupling with a hydraulic vibration damper. The flexible coupling with the hydraulic vibration damper according to an embodiment of the present invention damps torsional vibration of a driving shaft, such as a crank shaft of an engine, reduces vibration and noise of a driven shaft, is easy in manufacturing and installation because it is simple in structure and the damper and the coupling are integrated with each other, enhances economic feasibility and functionality, provides a normal damping function while continuously keeping oil pressure even though oil for damping is not supplied from the outside, and carries out transmission and absorption of torque and absorption of vibration variably. The flexible coupling with the hydraulic vibration damper comprises: a disk-shaped driving structure which has a driving shaft connected to the central portion thereof so as to rotate integrally, an installation space formed between the central portion and the rim portion, and a number of fixing holes formed along the outer circumferential surface of the central portion and the inner circumferential surfaces of the edge portion; a plurality of plate springs radially arranged in the installation space in such a way that both end portions are located at the fixing holes formed in the central portion and the rim of the driving structure; a plurality of inertial masses respectively arranged in divided spaces of the installation space radially formed by the plate spring; a driven shaft connection ring to which the inertia masses are connected and the driven shaft is connected so that the driven shaft is rotated integrally; oil for damping charged in the installation space in which the inertia masses are arranged; and a disk-shaped cover plate connected with the driving structure to prevent a leakage of oil for damping by sealing the installation space in which the inertia masses are arranged.

Description

Flexible coupling with hydraulic vibration damper

The present invention relates to a flexible coupling combined with an axial vibration hydraulic vibration damper, and more particularly, to reduce torsional vibration of a drive shaft such as an engine crankshaft while reducing vibration and noise of a driven shaft. Integrates the coupling with the coupling, facilitating the manufacture and installation, and at the same time improving the economics and functionality, and even if the oil for damping is not supplied from the outside, the oil pressure is continuously maintained to perform the normal damping function. The present invention relates to a flexible coupling combined with an axial vibration hydraulic vibration damper capable of smoothly and variably transmitting and absorbing and absorbing vibration.

The crankshaft is installed in an internal combustion engine such as a diesel engine of a ship or a gasoline engine of a vehicle to convert a reciprocating motion of a piston into a rotational motion. Such a crankshaft is used to detect the impact force generated during the explosion stroke of an internal combustion engine during a rotational motion. It is common to receive torsional vibrations.

Torsional vibration of the crankshaft generated as described above decreases the efficiency of the engine, while resonant phenomena generated when the forced vibration of the crankshaft due to the natural vibration and impact force of the crankshaft are generated at the same frequency are included in the crankshaft. Torsional vibration dampers are generally installed on the crankshaft of the engine to prevent damage to the engine components.

This torsional vibration damper reduces the torsional vibration and prevents the occurrence of resonance by using the viscosity of the fluid or the elasticity of the elastic body. In particular, the vibration damping caused by the viscosity of the fluid and the vibration damping by the elastic body are performed simultaneously. As one vibration damper, Korean Patent Publication No. 10-0845983, "Hydraulic Spring-type Torsional Vibration Damper", Registration No. 10-0921698, "Torsion Vibration Damper", and the like are provided.

The "hydraulic spring-type torsional vibration damper" includes a hub ring (7) connected to the crankshaft (1) of the engine; A circle ring 9 disposed at an outer side of the hub ring 7 at predetermined intervals; The hub ring 7 and the circle ring 9 are connected to each other at regular intervals along the circumferential direction between the hub ring 7 and the circle ring 9 to form a plurality of spaces 13 along the circumferential direction. A plurality of pressure plates 11; It is installed in the space 13 between the hub ring (7) and the circle ring (9) partitioned by the pressure plate 11 to form an oil chamber (15) filled with oil on both sides of the pressure plate (11) An inertial mass 17; A steel spring 19 fixed to the hub ring 7 to elastically support the inertial mass 15; Inner and outer cover plates 21 and 23 disposed on both outer sides of the inertial mass 17, the hub ring 7, and the circle ring 9, which are integrally coupled to the inertial mass 17 by bolts 25 and fastened together. It consists of a configuration comprising a.

Further, the "torsional vibration damper" has an inner hub ring 7 and an outer circle ring 9 having the same center and spaced apart from each other; Both ends are fixed to the hub ring 7 and the circle ring 9 in a radial direction so as to transmit the rotational movement of the hub ring 7 to the circle ring 9, along the circumference of the hub ring 7. A pressure plate 11 provided with a plurality of spaced apart from each other; Elastic plates are radially installed between neighboring pressure plates 11, respectively, and both ends are positioned in engaging grooves 7b and 9b formed on the outer circumferential surface of the hub ring 7 and the inner circumferential surface of the circle ring 9, respectively. (20) (20 '); An inertial mass 17 installed between the pressure plates 11 and the elastic plates 20 and 20 'adjacent to each other, so that an oil receiving space 15 is formed along the outer periphery of the upper and lower sides and the side; ; The inner and outer cover plates 21 and 23 are fastened to upper and lower surfaces of the inertial mass 17 to seal the oil receiving space 15.

However, the conventional vibration damper as described above performs only a function of attenuating the torsional vibration of the crankshaft coupled to the crankshaft of the engine, so that a separate coupling must be provided to connect the driven shaft to the crankshaft of the engine. There was a feeling. In addition, in the conventional vibration damper, an oil supply device for supplying the damping oil is separately provided and should be installed outside the vibration damper.

Republic of Korea Patent Publication No. 10-0845983 "Hydraulic Spring Torsional Vibration Damper" Republic of Korea Patent Publication No. 10-0921698 "Torsion Vibration Damper"

Therefore, the present invention improves the problems of the prior art, the inertial mass, the plate spring, damping oil disposed between the drive structure and the driven structure while the drive structure to which the drive shaft is coupled and the driven structure to which the driven shaft is coupled together By providing a structure in which torque transmission and vibration absorption are performed, the torsional vibration damping of the drive shaft and the vibration / noise reduction of the driven shaft can be simultaneously achieved, while the damper and the coupling are integrated into a simple structure to manufacture and install. It is an object of the present invention to provide a new type of axial vibration-hydraulic vibration damper and flexible coupling, which is both easy and economical and functional.

In addition, the present invention provides an oil pressure maintaining device including an air bellows, a piston, a spring, a plug is installed therein to maintain the pressure of the damping oil, even if the damping oil is not supplied from the outside It is an object of the present invention to provide a new type of axial vibration hydraulic vibration damper and flexible coupling capable of performing the normal damping function while maintaining the pressure continuously.

In addition, the present invention by using a multi-layer leaf spring consisting of a plurality of leaf springs to transmit torque and absorb the vibrations to combine the new type of axial vibration hydraulic vibration damper that can be made to smoothly and variably smooth the transmission and absorption of vibrations and absorption of vibrations It is an object to provide a flexible coupling.

According to a feature of the present invention for achieving the above object, the present invention is made of a disk body shape that the drive shaft is integrally rotated by being coupled to the central portion, the installation space is formed between the central portion and the edge portion, the outer peripheral surface and A drive structure in which a plurality of fixing grooves are formed along an inner circumference of the edge portion; A plurality of leaf springs disposed radially in the installation space such that both ends are positioned in respective fixing grooves formed at the center and the edge of the drive structure; A plurality of inertial masses each disposed in a divided space of the installation space radially formed by the leaf springs; A driven shaft coupling ring to which the plurality of inertial masses are connected, and a driven shaft is coupled to rotate integrally; A damping oil filled in the installation space in which the inertial mass is disposed; It is made of a disk-shaped coupled to the drive structure, and provides a flexible coupling combined with the axial vibration hydraulic vibration damper including a cover plate to seal the installation space in which the inertial mass is disposed to prevent the leakage of the damping oil. do.

In such a flexible coupling for axial vibration hydraulic vibration damper according to the present invention, the drive structure is formed in the center portion, and formed of a hollow cylindrical shape the drive shaft is inserted, the drive shaft coupling ring is formed with a fixed groove around the outer peripheral surface and ; A casing ring spaced apart from the drive shaft coupling ring, formed in an edge portion, formed in a ring shape, and having a fixing groove formed around an inner circumferential surface thereof; Comprising a disc shape to form the bottom surface of the installation space, the drive shaft coupling ring is formed to extend from the center portion, and the casing disc for forming the casing ring extending from the edge portion is integrally molded.

The leaf spring in the axial vibration-hydraulic damper combined flexible coupling according to the present invention includes a central leaf spring having both ends freely arranged in each of the fixing grooves formed in the center and the edge of the drive structure; It consists of a multi-layer leaf spring having a shorter length than the center leaf spring and including a pair of side leaf springs arranged and coupled to both sides of the center leaf spring.

In the flexible coupling combined with the axial vibration-hydraulic vibration damper according to the present invention, the plurality of inertial masses and the driven shaft coupling ring are integrally formed to form a driven structure, and the driven structure is formed around the outer peripheral surface of the lower end of the driven shaft coupling ring. The plurality of inertial masses are radially spaced apart from each other, such that the drive shaft coupling ring is disposed inside the driven shaft coupling ring so that the drive structure and the driven structure are assembled to each other.

The first oil cover plate for closing the inner open surface of the drive shaft coupling ring in the flexible coupling for the axial vibration hydraulic vibration damper according to the present invention; A second oil cover plate for closing an inner open surface of the driven shaft coupling ring; Including the oil seal in close contact with the inner peripheral surface of the central flange of the cover plate and the outer peripheral surface of the driven shaft coupling ring, the damping oil is filled in the space formed inside the first oil cover plate, the second oil cover plate, the oil seal. .

Such a flexible coupling combined with the axial vibration hydraulic vibration damper according to the present invention includes a cylindrical air bellows inserted into a groove formed on an outer circumferential surface of the inertial mass and expanded according to the pressure of air filled therein; A piston inserted into a recess of the inertial mass and disposed outside the air bellows; A spring inserted into the groove of the inertial mass and disposed outside the piston; The apparatus further includes an oil pressure holding device disposed outside the spring and including a plug to close the groove of the inertial mass.

According to the flexible coupling for combined use of the axial vibration hydraulic vibration damper according to the present invention, by providing a configuration in which the damper and the coupling are integrated in a simple configuration, the torsional vibration damping of the drive shaft and the vibration noise of the driven shaft can be simultaneously reduced. In addition, it is possible to improve economics and functionality at the same time, and to be easily manufactured and installed, and to maintain a normal damping function while maintaining the oil pressure even if the damping oil is not supplied from the outside by the oil pressure holding device. By the multi-layered leaf spring, transmission and absorption of torque and absorption of vibration can be made smoothly and variably.

1 is an exploded perspective view of a flexible coupling combined with an axial vibration hydraulic vibration damper according to an embodiment of the present invention;
Figure 2 is an assembly view of the flexible coupling combined axial vibration hydraulic vibration damper according to an embodiment of the present invention;
3 is a horizontal cross-sectional view of a main portion of a flexible coupling combined with an axial vibration hydraulic vibration damper according to an embodiment of the present invention;
Figure 4 is a vertical cross-sectional view of the flexible coupling for axial vibration hydraulic vibration damper according to an embodiment of the present invention;
5 (a) and (b) is a view for showing the configuration and operation of the multi-layer leaf spring constituting the flexible coupling combined with the axial vibration hydraulic vibration damper according to an embodiment of the present invention;
Figure 6 (a) and (b) is a view for showing the configuration and operation of the oil pressure holding device constituting the flexible coupling combined with the axial vibration hydraulic vibration damper according to an embodiment of the present invention;
7 is an exploded perspective view of a flexible coupling for combined axial vibration hydraulic vibration damper according to another embodiment of the present invention with a different structure of the driven structure;
8 is a view illustrating a configuration in which the flexible coupling combined with the axial vibration hydraulic vibration damper according to the embodiment of the present invention is integrated with a flywheel.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. On the other hand, in the drawings and detailed description showing and referring to the construction and operation easily understood by those skilled in the art from the general vibration damper, coupling, leaf spring, oil, oil seals, etc. are omitted or omitted. In the drawings and specification, there are shown in the drawings and will not be described in detail, and only the technical features related to the present invention are shown or described only briefly. Respectively.

Flexible coupling 100 combined with the axial vibration hydraulic vibration damper according to an embodiment of the present invention is a drive structure 10, a plurality of leaf springs 20, a plurality of inertial masses 30 and the blood as shown in Figs. A driven structure 50 composed of a coaxial coupling ring 40, a damping oil 60, a cover plate 70, a first oil cover plate 85, a second oil cover plate 86, an oil seal 87, Consists of the oil pressure holding device 80, the coupling function for connecting the drive shaft (1) and the driven shaft (2) and the torsional vibration damping of the drive shaft (1) and the driven shaft (2) as shown in FIG. The damper function for vibration / noise reduction of) is performed at the same time. Here, the drive shaft 1 may be a crankshaft of the engine when the drive shaft 1 is applied to the engine when the flexible coupling 100 combined with the axial vibration hydraulic vibration damper according to the embodiment of the present invention. Of course, the flexible coupling 100 combined axial vibration hydraulic damper according to an embodiment of the present invention can be applied to various fields in addition to the engine.

The drive structure 10 is formed in a disk shape in which the drive shaft 1 is coupled to the center portion and rotates integrally. An installation space 14 is formed between the center portion and the edge portion to form a plurality of leaf springs 20 and a plurality of leaf springs. Two inertial masses 30 and damping oil 60 are arranged in the installation space 14. The driving structure 10 includes a plurality of fixing grooves 111 and 121 formed around the center outer circumferential surface and the edge inner circumferential surface to fix the plurality of leaf springs 20, respectively. The drive structure 10 according to the embodiment of the present invention for this purpose consists of a configuration including a drive shaft coupling ring 11, casing ring 12, casing disc (13).

The drive shaft coupling ring 11 is formed at the center of the drive structure 10, and has a hollow cylindrical shape having a drive shaft insertion hole 112, whereby the drive shaft 1 is inserted therein, and the fixing groove 111 is formed around the outer circumferential surface thereof. Is formed.

The casing ring 12 is formed at the edge portion spaced outward from the drive shaft coupling ring 11 and forms a concentric circle structure with the drive shaft coupling ring 11. The casing ring 12 is formed in a ring shape, the fixing groove 121 is formed along the inner circumferential surface. Here, the fixing grooves 111 and 121 formed in the drive shaft coupling ring 11 and the casing ring 12 are formed larger than both ends of the leaf spring 20 so that both ends of the leaf spring 20 are fixed groove 111. Allow movement within 121.

The casing disc 13 is formed in a disc shape to form the bottom surface of the installation space 14. The drive shaft coupling ring 11 extends from the center of the casing disc 13, and the casing ring 12 is casing disc. (13) It extends from an edge part and is formed. As such, the drive shaft coupling ring 11, the casing ring 12, and the casing disc 13 are integrally formed to form a single body.

The plurality of leaf springs 20 are disposed radially in the radial direction in the installation space 14 such that both ends are positioned in each of the fixing grooves 111 and 121 formed at the center and the edge of the drive structure 10. Here, the leaf spring 20 according to the embodiment of the present invention has a central leaf spring 21, both ends of which are freely disposed at each of the fixing grooves 111 and 121 formed at the center and the edge of the drive structure 10, It has a shorter length than the center leaf spring 21 and consists of a multi-layer leaf spring composed of a pair of side leaf springs 22 which are arranged and coupled to both sides of the center leaf spring 21. Here, both ends of the side leaf spring 22 are positioned outside the fixing grooves 111 and 121 without being inserted into each of the fixing grooves 111 and 121 formed at the center and the edge of the driving structure 10. The leaf spring 20 is accommodated in the damping oil 60 filled in the installation space 14 to perform a damping function together with the damping oil 60, while the drive shaft 1 is coupled to the drive structure. Torque is transmitted from 10 to the driven structure 50 to which the driven shaft 2 is coupled.

When the leaf spring 20 according to the embodiment of the present invention is subjected to a torque smaller than the set size, both ends of the central leaf spring 21 are fine inside the fixing grooves 111 and 121 as shown in FIG. Torque absorption and vibration damping function are performed while bending deformation and fine vibration. In addition, when a torque of more than a predetermined size is received, as shown in FIG. 20 is absorbed by the drive shaft 1 while part of the torque transmitted from the drive shaft 1 is transmitted to the driven shaft 2. Of course, the central leaf spring 21 in FIG. 5 (b), which receives a torque greater than or equal to a set size, also performs torque absorption and vibration attenuation while fine bending deformation and fine vibration in the fixing grooves 111 and 121. . Thus, the leaf spring 20 according to the embodiment of the present invention is gradually bent change behavior and micro-vibration behavior in accordance with the torque increase, so as to act differently in accordance with the magnitude of the torque transfer and absorption of the torque Therefore, the vibration damping function is effectively performed. That is, the leaf spring 20 according to the embodiment of the present invention can be sensitive to the vibration displacement through the elastic displacement of both ends as the end is made of the free end, the reaction force increases even in the minimum torque state, the maximum As the maximum displacement in the torque state can be corresponded to the bending deformation of the entire multilayer leaf spring 20, the torque transmission, absorption, and vibration damping functions are increased.

On the other hand, while the resonance frequency dispersion with the drive shaft 1 is induced by the elastic deformation of the leaf spring 20, the resonance phenomenon of the drive shaft 1 is prevented.

The plurality of inertial masses 30 are disposed in the divided spaces of the installation space 14 formed radially by the plurality of leaf springs 20, and the inertial masses 30 have a fan shape. Then, a bearing bush 33 is formed on the upper surface of the inertial mass 30 so as to contact the bottom surface of the cover plate 70. Such a plurality of inertial masses 30 are also accommodated in the damping oil 60 filled in the installation space 14 to perform a damping function together with the damping oil 60, while the driving shaft 1 is coupled. Torque is transmitted from the drive structure 10 to the driven structure 50 to which the driven shaft 2 is coupled. On the other hand, the inertial mass 30 is formed with a groove 31 into which the oil pressure holding device 80 is installed on the outer circumferential surface thereof, while an oil moving groove 32 communicating with the groove 31 is formed on one surface thereof ( 6, the damping oil 60 is also filled in the oil moving groove 32 and the recess 31 of the inertial mass 30.

The driven shaft coupling ring 40 is a plurality of inertial masses 30 are connected, the driven shaft 2 is coupled to rotate integrally, in a hollow cylindrical shape having a driven shaft insertion hole 41 Is done. The plurality of inertial masses 30 and the driven shaft coupling ring 40 are integrally formed to form a driven structure 50, which is driven along the outer circumference of the lower end of the driven shaft coupling ring 40. The plurality of inertial masses 30 are radially spaced apart from each other. Accordingly, the driven structure 50 forms a horizontal slit 51 into which the leaf springs 20 are inserted between the plurality of inertial masses 30, while the horizontal slit is formed around the lower end of the driven shaft coupling ring 40. A vertical slit 52 is formed to be connected to 51.

Here, as the drive shaft coupling ring 11 is disposed inside the driven shaft coupling ring 40, the drive structure 10 and the driven structure 50 are assembled with each other. That is, the drive structure 10 and the driven structure 50 are assembled with each other while the inertial mass 30 is fitted into each divided space of the installation space 14 in which the leaf spring 20 is disposed.

Meanwhile, as shown in FIG. 7, a plurality of inertial masses 30 protrude from the bottom edge portion of the upper disc 34, and the driven shaft coupling ring 40 protrudes from the upper surface of the upper disc 34. A driven structure 50 'may be formed. Since the inertial mass 30 and the driven shaft coupling ring 40 are integrally formed at the upper and lower sides of the disk, the driven structure 50 'can be easily and smoothly casted to reduce production costs. You can do it.

The damping oil 60 is filled in the installation space 14 in which the inertial mass 30 is disposed. As the damping oil 60 flows according to the vibration displacement of the leaf spring 20, the damping oil 60 is damped. Damping function is performed by the viscosity of.

Here, the flexible coupling 100 combined with the axial vibration hydraulic vibration damper according to the embodiment of the present invention vibrates through the inertial mass of the inertial mass 30 and the elastic deformation of the leaf spring 20 and the viscous behavior of the damping oil 60. And noise reduction functions.

The cover plate 70 is formed in the shape of a disk body that is coupled to the drive structure 10. To this end, bolt holes 122 and 73 are formed on surfaces corresponding to each other in the casing ring 12 of the cover plate 70 and the driving structure 10 to be coupled to each other by the fastening bolts 74. In addition, the cover plate 70 forms a central hole 72 so that the driven shaft coupling ring 40 of the driven structure 50 passes through the central hole 72 of the cover plate 70 to protrude outward. The cover plate 70 seals the installation space 14 in which the inertial mass 30 is disposed, thereby preventing the leakage of the damping oil 60.

The first oil cover plate 85 closes the inner open surface of the drive shaft coupling ring 11, and the second oil cover plate 86 closes the inner open surface of the driven shaft coupling ring 40, and the oil seal. Denoted at 87 is in close contact with the inner circumferential surface of the central flange 71 of the cover plate 70 and the outer circumferential surface of the driven shaft coupling ring 40. Accordingly, the damping oil 60 is filled in the space formed inside the first oil cover plate 85, the second oil cover plate 86, and the oil seal 87 without external leakage.

The oil pressure holding device 80 is inserted into the groove 31 formed on the outer circumferential surface of the inertial mass 30 and includes an air bellows 81, a piston 82, a spring 83, and a plug 84. It consists of a configuration.

The air bellows 81 is inserted into a recess formed in the outer circumferential surface of the inertial mass 30, and is formed in a bellows cylindrical shape that is expanded according to the pressure of air filled therein. The piston 82 is inserted into the recess 31 of the inertial mass 30 to be disposed outside the air bellows 81, and the spring 83 is inserted into the recess 31 of the inertial mass 30 to form the piston 82. ) And the plug 84 is disposed outside the spring 83 to close the groove of the inertial mass 30.

When the damping oil 60 is overexpanded, the oil pressure holding device 80 expands the expansion volume of the damping oil 60 while the air bellows 81 is reduced as shown in FIG. The piston 82 is installed in a direction in which centrifugal force acts as shown in FIG. 6 (b) even when the damping oil 60 is placed in a low pressure condition due to leakage of the damping oil 60 or the like. The damping oil 60 is pressurized by the rotary centrifugal force so that the pressure of the damping oil 60 is maintained at a set size or more.

Meanwhile, the flexible coupling 100 combined with the axial vibration hydraulic vibration damper according to the embodiment of the present invention may be integrally formed with the flywheel 200 as shown in FIG. 7 when applied to an engine. The gear 210 is engaged with the drive gear 310 of the starting drive motor 300.

The flexible coupling 100 combined with the axial vibration hydraulic vibration damper according to the embodiment of the present invention constituted as described above is connected to the drive shaft 1 and the driven shaft 2 in a separated state, while transmitting a torque plate. Since the central leaf spring 21 constituting the spring 20 is in contact with the drive structure 10 with a minimum area, noise generation is minimized. Accordingly, the driving part and the driven part are connected by fastening bolts, thereby overcoming the problems of the prior art in which noise of a predetermined size or more can be effectively applied to passenger cars, submarines, and the like.

In addition, the flexible coupling 100 combined axial vibration hydraulic vibration damper according to an embodiment of the present invention is characterized in that the manufacturing is simplified as the driven shaft coupling ring 40 and the plurality of inertial masses 30 are integrally molded In this case, the damping oil 60 filled in the sealed installation space 14 may be maintained at a hydraulic pressure of the damping oil 60 by the centrifugal force and the oil pressure maintaining device 80 according to rotation. As a result, even if the damping oil is not supplied from the outside, the pressure of the damping oil 60 in the pressurized state is continuously maintained to perform a normal damping function.

As described above, the axial vibration hydraulic vibration damper combined flexible coupling according to the embodiment of the present invention has been shown in accordance with the above description and drawings, but this is only an example and within the scope not departing from the technical spirit of the present invention. It will be appreciated by those skilled in the art that various changes and modifications are possible.

1: drive shaft 2: driven shaft
10 drive structure 11 drive shaft coupling ring
111, 121: fixing groove 112: drive shaft insertion hole
12: casing ring 122, 73: bolt hole
13: casing disc 14: installation space
20: leaf spring 21: center leaf spring
22: side leaf spring 30: inertial mass
31: groove 32: oil moving groove
33: bearing bush 34: upper disc
40: driven shaft coupling ring 41: driven shaft insertion hole
50, 50 ': driven structure 51: horizontal slit
52: vertical slit 60: damping oil
70: cover plate 71: flange
72: center hole 74: fastening bolt
80: oil pressure holding device 81: air bellows
82: piston 83: spring
84: plug 85: the first oil cover plate
86: second oil cover plate 87: oil seal
100: flexible coupling with vibration damper
200: flywheel 210: starting gear
300: drive motor for starting 310: drive gear

Claims (6)

The drive shaft (1) is formed in the shape of a disc body is rotated integrally coupled to the central portion, the installation space 14 is formed between the central portion and the edge portion, a plurality of fixing grooves around the outer peripheral surface of the central portion and the inner peripheral surface of the edge portion ( A drive structure 10 on which 111 and 121 are formed;
A plurality of leaf springs (20) disposed radially in the installation space (14) such that both ends are positioned in each of the fixing grooves (111) (121) formed at the center and the edge of the drive structure (10);
A plurality of inertial masses 30 disposed in divided spaces of the installation space 14 radially formed by the leaf springs 20;
A driven shaft coupling ring (40) to which the plurality of inertial masses (30) are connected and to which the driven shaft (2) is coupled to rotate integrally;
A damping oil 60 filled in the installation space 14 in which the inertial mass 30 is disposed;
The cover plate is formed in a disk shape coupled to the drive structure 10 and seals the installation space 14 in which the inertial mass 30 is disposed to prevent leakage of the damping oil 60. 70),
The drive structure 10 is formed in the center portion, the drive shaft coupling ring 11 is formed in a hollow cylindrical shape is inserted into the drive shaft (1), the fixing groove 111 is formed along the outer circumferential surface;
A casing ring (12) spaced apart from the drive shaft coupling ring (11), formed in an edge portion, formed in a ring shape, and having a fixing groove formed along an inner circumferential surface thereof;
Comprising a disk shape to form the bottom surface of the installation space 14, the drive shaft coupling ring 11 is formed to extend from the center portion, the casing ring 12 is formed to extend from the edge portion 13 is integrally molded,
A first oil cover plate (85) for closing the inner open surface of the drive shaft coupling ring (11);
A second oil cover plate (86) for closing the inner open surface of the driven shaft coupling ring (40);
An oil seal 87 disposed in close contact with the inner circumferential surface of the central flange of the cover plate 70 and the outer circumferential surface of the driven shaft coupling ring 40;
Flexible coupling for axial vibration hydraulic vibration damper, characterized in that the damping oil 60 is filled in the space formed inside the first oil cover plate 85, the second oil cover plate 86, the oil seal 87 . delete The method of claim 1,
The leaf spring 20 includes a central leaf spring 21 having both ends freely disposed at respective fixing grooves formed at the center and the edge of the drive structure 10;
Flexible coupling for axial vibration hydraulic vibration damper, characterized in that it consists of a multi-layer leaf spring having a shorter length than the center leaf spring 21 and including a pair of side leaf springs 22 disposed on both sides of the center leaf spring and coupled to each other. . The method of claim 1,
The plurality of inertial masses 30 and the driven shaft coupling ring 40 are integrally molded to form driven structures 50 and 50 ',
The driven structure 50, 50 ′ allows the plurality of inertial masses 30 to be radially spaced apart from each other along the outer circumferential surface of the lower end of the driven shaft coupling ring 40.
The drive shaft coupling ring 11 is disposed inside the driven shaft coupling ring 40, and the drive structure 10 and the driven structure 50 and 50 'are assembled to each other. Coupling. delete 5. The method of claim 4,
A cylindrical air bellows 81 inserted into the recess 31 formed on the outer circumferential surface of the inertial mass 30 and expanded according to the pressure of the air filled therein;
A piston (82) inserted into the groove (31) of the inertial mass (30) and disposed outside the air bellows (81);
A spring (83) inserted into the groove (31) of the inertial mass (30) and disposed outside the piston (82);
An axial vibration hydraulic vibration damper, characterized in that it further comprises an oil pressure holding device (80) disposed outside the spring (83) to close the groove (31) of the inertial mass (30). Combined flexible couplings.

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