SU1707346A1 - Friction device - Google Patents

Abstract

The invention relates to mechanical engineering, namely to disk friction devices. The purpose of the invention is to improve performance by providing various smoothness of frictional interaction depending on the direction of rotation, as well as improving speed. Pressure discs (LP) 3 and 4 are strutted by springs 5 and mounted with the possibility of relative rotation and axial movement. The reinforcement link consists of rolling bodies 7 placed in slots of variable depth on the end faces of LD 3 and 4 facing one another.

Description

The invention relates to mechanical engineering, namely to disk friction devices.

A disc brake is known, comprising a housing that is mounted with the possibility of rotation relative to the housing shaft, spring-loaded one to the other and mounted with the possibility of relative rotation and axial movement of the pressure discs, the reinforcement element in the form of variable depth slots placed on facing one the other ends of the pressure discs, rolling elements, friction elements mounted with the possibility of axial interaction with the pressure discs, the shaft and the housing, a linear actuator associated with the housing and Complete with a linearly mounted pressure element relative to the housing, a mechanism for converting linear to rotational movement associated with the linear actuating element of the linear actuator and with one of the pressure disks.

The disadvantages of the known friction device are its low performance due to the presence of a drive mechanism in the form of a lever system, which has a large number of structural relationships that complicate the design. It does not ensure the response speed of the device, as well as change the smoothness of the friction interaction when contacting the friction surfaces of friction elements with a variable direction of rotation of the moving parts of the device relative to each other.

The aim of the invention is to improve the performance of a friction device by providing speed

operation and various smoothness of the frictional interaction depending on the direction of rotation.

This goal is achieved by the fact that in a friction device comprising a housing mounted for rotation relative to the housing shaft, spring-loaded one to the other and mounted for relative rotation and axial movement of the pressure disks, the reinforcement element in the form of variable depth slots made on the end faces of the pressure plates facing one another, the rolling elements, friction elements mounted with the possibility of axial engagement with at least one of the pressure disks, scarlet and casing, linear actuator associated with the casing and configured with a pressure element mounted for linear movement relative to the casing, a mechanism for converting linear displacement into a rotary one associated with a pressure element of the linear actuator and one of the pressure disks, the second pressure disk is fixed from rotation relative to the shaft, the mechanism for converting linear to rotary motion is associated with the shaft and is made in the form of elements of a non-self-braking screw pair, one of which is fixed van against rotation relative to the shaft, and the second - relative to the first pressure plate.

In the friction device of a normally open type, one of the elements of the non-braking screw pair is made in the form of a finger. The second element is in the form of a groove in which the said finger is located, the groove is made in the shaft, the finger is installed in the first pressure plate, the latter is fixed

from axial movement relative to the pressure element by means of a protrusion formed therein and an annular groove made in the first pressure disk, in which said protrusion is located, and the friction elements are rigidly fixed on the ends of the pressure disks, the second of which is mounted with the possibility of axial movement relative to the shaft.

A normally closed type friction device is fitted with a sleeve that is axially displaced relative to the first pressure disc by means of guide rods, the first pressure disc is rigidly mounted on the shaft, the second pressure disc is rotatably and axially displaced on the shaft, the first element is a non-braking screw pair made in the form of at least one protrusion, which is placed on the sleeve, the second element of the specified pair is made in the form of at least one screw n The asex on the outer surface of the rim of the second pressure disc in which the specified protrusion is located, while the sleeve is installed with the possibility of limited axial movement relative to the spring-loaded pressure element by means of an additional protrusion performed on the latter and an annular groove in the sleeve, in which said additional protrusion is located the elements are made in the form of friction disks that are alternately connected to the shaft and the housing and which are arranged with possible Tew axial engagement with the housing and the second pressure plate.

The linear drive of the friction device is made in the form of an inductor, which is rigidly connected to the body, and the pressure element is in the form of a core, which is mounted with the possibility of axial movement relative to the inductor by means of guide elements.

1 shows a friction device of a normally open type, a general view; FIG. 2 shows a friction device of a normally closed type. General view; FIG. 3 is a section A-A in FIG. 1.2; nafig.4-section B - B in figure 2; figure 5 - section b - b in figure 4.

The friction device (in Fig. 1.2) comprises a housing 1, a shaft 2 with pressure discs 3 and 4, which are mounted by springs 5 and mounted for relative rotation and axial movement, an amplifying element 6 consisting of rolling bodies 7 (balls or rollers ) placed in slots 8 of variable depth of a triangular shape facing one

to the other ends of the pressure discs, the friction elements 9-12, which are mounted with the possibility of axial interaction with at least one of the pressure discs,

5 with a shaft and a housing; a linear actuator 13 in the form of an inductor 14 with an excitation winding 15, rigidly connected to the housing and made with a pressure element 16 in the form of a core mounted on guide elements

0 17c with the possibility of translational movement relative to the body, the mechanism 18 for converting linear movement into rotational, formed by elements of a non-braking spacing screw,

5 For a normally open type friction device (Fig. 1, 3), the first pressure disk 3 is mounted on the shaft 2 with the possibility of axial movement and rotation relative to the second pressure disk 4, which is mounted on the splined part of the shaft 19 with the possibility of axial movement. The pressure element 16 has a protrusion 20, which is located in the annular groove 21 of the hub 22 of the first pressure

disk 3 and fixes this disk against axial movement relative to the pressure element. The first element of the non-braking mechanism of the screw pair of the mechanism 18 is made in the form of a finger 23 and is fixedly mounted in

0 the hub 22 of the first pressure disc 3, and the second element of this pair is made in the shaft 2 in the form of a screw groove 24 in which the finger 23 is located. The friction elements in the form of friction linings 9 and 10 are rigid

5 mounted on the ends of the pressure discs.

For a normally closed-type friction device (FIGS. 2-5), the first pressure disk 3 is fixed on the shaft 2 rigidly, the second pressure disk 4 is installed on the shaft

0 with the possibility of rotation and axial movement relative to the disk 3. On the guide rods 25 of the first pressure disk, a sleeve 26 is installed with the possibility of axial movement relative to

5 of this disc. The pressure element 16 is spring-loaded closing springs 27 and is made in the form of a glass with protrusions 28, which are located in the annular groove 29 of the sleeve 26 and limit its axial

0 move relative to the pressure element. The first element of the non-self-locking screw pair of mechanism 18 is made in the form of at least one protrusion 30 on the inner surface of sleeve 26, and the second element of this pair is in the form of at least one screw groove 31 on the outer surface of the rim of the second pressure disc 4. and which are the protrusions 30. The friction elements are made in

0 type flat packaged 11 and concave 12 friction discs alternately connected with the slotted sleeve of the shaft 32 and the slotted part of the housing 33.

Friction device normally open type (Fig. 1.3) works as follows.

The friction device is turned on by applying voltage to the exciter winding 15 of the inductor 14, while the pressure element 16 is attracted to it by the action of electromagnetic force and, moving progressively along the guide elements 17, interacts with its protrusion 20 with an annular groove

21 of the hub 22 of the first pressure disc 3, which ensures the translational movement of the latter along the axis of the shaft, and the hub

22 of the first pressure disk 3, through a fixedly mounted finger 23, interacts with a non-braking screw groove 24 in the shaft 2 and rotates the disk 3 at a certain angle relative to the second pressure disk 4, while the rolling bodies 7 located in slots 8 on one facing the other the ends of the pressure discs move along their inclined surfaces and push the discs apart, moving the disk 4 along the splined part of the shaft 19. and the disk 3 in the opposite direction from it. As a result, the friction linings 9,, 10, rigidly mounted on the ends of the pressure discs 3. 4. begin to contact with the housing 1..

In a normally open-type frictional device, a propping force to provide the necessary degree of reinforcement increases faster with an increase in the inclination angle of the non-self-locking braking groove 24 in the shaft 2 to the maximum permissible value. In the process of contacting the friction surfaces of the friction linings 9, 10 of the pressure discs 3, 4 with the body 1, the proppant force builds up under the action of the friction forces that are directed in the direction of rotation of the body or shaft and accelerate the rotation of the pressure disk 3 in the screw groove 24 with respect to the pressure disk 4, if the disk 3 is turned in the direction of their rotation. With a change in the direction of rotation of the housing or shaft and the effects of friction during the contacting of the friction linings 9. 10 disks 3.4 with the housing 1, rotation of the disk 3 in the screw slot 24 relative to the disk 4 slows down and the smoothness of the friction interaction of the friction surfaces increases.

Thus, the friction device (Fig. 1.3) provides a different smoothness of the friction interaction.

friction surfaces of overlays 9, 10 of pressure plates 3. 4 with body 1, depending on the direction of rotation, which is achieved, as when it operates in the brake mode for

deceleration of the rotating shaft relative to the stationary body or rotating body relative to the stationary shaft, and when operating in clutch mode, when case 1 is the drive shaft, and shaft 2 with the pressure disks 3, 4 is the follower or, conversely, for coupling the friction friction surfaces the overlays 9, 10 of the pressure disks 3, 4 and the casing 1 with the transmission of the torque from the driving element to the driver.

The friction device is disconnected when the exciter winding 15 is de-energized by the inductor 14. In this case, the springs 5 turn the pressure discs

0 3, 4 and return the roll bodies 7 to the deepest part of the sockets 8 when the first and second pressure plates move counter to the shaft, which is fixed by its protrusion and the stop ring, as a result

5, between the case 1 and the friction linings 9, 10 of the pressure plates 3. The shaft 2 exposes the necessary axial clearance, and the case and the shaft can freely rotate relative to each other, interacting between

0 through the protrusion 20 of the pressure element 16. located in the annular groove 21 of the hub 22 of the first pressure disc 3.

The friction device of a normally closed type (Figures 2–5) operates as follows.

The device is turned on by relieving the voltage of the inductor 14 excitation winding 15, while the pressure element 16 is moved along the guide elements 17 by the action of the closing spring 27, interacting with its protrusions 28 with the annular groove 29 of the sleeve 26, ensures its movement along the guide rods m 25 of the first pressure disc 3, and the sleeve 26 with the projections 30 on its inner surface interact with screw grooves 31 on the outer surface of the rim of the second pressure disc 4, turning it through a certain angle relative to The first pressure plate 3 fixed on the shaft 2 in such a way that the rolling bodies 7 located in the sockets 8 on the end faces of the pressure disks face one another move along their inclined surfaces, which ensures the forward movement of the second pressure disk 4 relative to the first pressure disk 3 and a propping force, under the action of which the second pressure disk 4 moves the flat friction

the disks 11 along the splined hub of the shaft 32 and the concave friction disks 12 i.o located between them in the splined part of the housing 33, compress their friction surfaces and ensure contact with the housing 1.

8, the friction device of a normally closed type proppant for providing the necessary degree of reinforcement increases more rapidly with increasing inclination angle of the non-braking screw grooves 31 on the outer surface of the rim of the second pressure disc 4 to the maximum allowable value. In the process of contacting the friction surfaces of the disks 4, 11, 12 and the housing 1, the propping force builds up under the influence of friction forces, which are directed in the direction of rotation of the housing 1 with concave friction disks 12 or shaft 2 with pressure disks 3, 4 and flat friction disks 11 and accelerate the rotation of the disk 4 from the translational movement of the projections 30 of the sleeve 26 in its screw grooves 31 on the outer surface of the rim relative to the pressure disk 3. By changing the direction of rotation of the housing 1 with the disks 12 or the shaft 2 with the disks 3, 4; 11 and the friction force of the disc 4 relative to the disc 3 is slowed down, and the smoothness of the frictional interaction increases.

Thus, the friction device (Figures 2–5) provides a different smoothness of the friction interaction of the friction surfaces of the disks 4, 11, 12 and the housing 1, depending on the direction of rotation, which is achieved, like during its operation in the brake mode for braking the rotating shaft relative to the stationary shaft, and when operating in clutch mode, when case 1 with disks 12 is driving, and shaft 2 with disks 3, 4, 11 is a follower or, conversely, for coupling the friction surfaces of disks 4, 11, 12 and case 1 s transmission of torque element to the slave.

The friction device is disconnected when the voltage is applied to the winding 15 of the inductor 14. Then the pressure element 16 is attracted to it by the action of electromagnetic force, moving along the guide elements 17 and compressing the closing springs 27, while its protrusions 28 are moving along the guides The rods 25 of the first pressure disc 3 in its direction, the sleeve 26 with the projections 30, which interact with the screw grooves 31 of the outer surface of the rim of the second pressure disk 4, rotate it through a certain angle and move it stupatelno relatively

rigidly mounted on the shaft 2 of the first push-button 3 so that the rolling bodies 7 start to return to the deepest part of the sockets 8 through their upper surface. Under the action of the springs 5, the second pressure disk 4 returns to its original position and releases the friction discs from the applied axial force, the latter, thanks to the spring

0, the action of the concave discs 32 quickly moves away from each other, and the necessary axial clearance is set between the friction surfaces. As a result, the housing and the shaft can freely rotate relative to each other.

Claims (4)

1. A friction device containing a housing mounted for rotation with respect to the housing shaft, spring-loaded one to another and pressure-mounted disks mounted with the possibility of relative rotation and axial movement, an amplifying element in the form of variable depth slots placed on facing one another the ends of the pressure discs, rolling body, friction elements installed with 0 the possibility of axial interaction with at least one of the pressure plates, the shaft and the housing, the linear actuator associated with the housing and configured to be linearly mounted 5 movement relative to the housing by a pressure member, a mechanism for converting a linear movement into a rotary, associated with a pressure element of a linear actuator and one of the pressure disks, characterized in that, in order to improve performance by providing different smoothness of the friction interaction depending on the direction of rotation , the second push-down disk is fixed against rotation relative to the shaft; the mechanism for converting linear to rotary motion is associated with the shaft and is designed as ementov nesamotormoz scheys screw 0 pairs, one of which is fixed against rotation relative to the shaft, and the second relative to the first pressure disk. 2. The device is popl.otlichuyuschee- with the fact that one of the elements of the non-self-5 rotary screw pair is made in the form of a finger, the second element is in the form of a groove in which the said finger is located, the groove is made in the shaft, the finger is installed in the first disk, the latter is fixed against axial movement relative to the pressure element by means of a protrusion formed therein and an annular groove made in the first pressure disk in which the protrusion is located, and the friction elements are rigidly fixed on the end faces of the pressure disks, the second and which is mounted with the possibility of axial movement relative to the shaft. 3. The device pop. 1, differs in order. that it is provided with a sleeve that is axially movable relative to the first pressure disk by means of guide rods, the first pressure disk is rigidly mounted on the shaft, the second pressure disk is rotatably and axially mounted on the shaft, the first element of the non-braking spindle , at least one protrusion that is placed on the sleeve, the second element of the specified pair is made in the form of at least one screw groove on the outer surface of the rim of the second pressure plate in which is located said protrusion, wherein the sleeve is installed with the possibility of limited axial movement relative to the spring-loaded pressure element by means of an additional projection made on the last one and an annular groove made on the sleeve, in which said additional projection is located, and the friction elements are made in the form of the package is alternately connected with the shaft and the casing of the friction discs, which are arranged, with the possibility of axial interaction with the casing and the second one on the pressing disk. 4. The device according to claim 1, 3, which is such that, in order to improve speed, the linear actuator is made in the form of an inductor, which is rigidly connected to the body, and the pressure element is in the form of the core, which is mounted with the possibility of axial movement relative to the inductor by means of guide elements. Priority points: 14.08.89 p.Z. 27 / 33 and but 93 X  Tt 9t I 2Ч echelon 50 FIG. five