SU916291A1 - Pneumatic percussion nut-driver - Google Patents

Description

Union of Soviet Socialist Republics DESCRIPTION Inventions TO AUTHOR'S CERTIFICATE "1) 916291 (61) Additional to author certificate woo - (22) 3Approved 0/05.80 (21) 2921032 / 25-28 (51) M. Cl | £ £ кы11 committee with the attachment of application No. - at 25 V 21/02 USSR (23) Priority - in made inventions Published 03/30/82. Bulletin No. ^ 2 (53) UDKb21.881 ι and discoveries Date published description 30.0382 (088.8)

I

The invention ^ relates to manual mechanized tools of shock-pulse action and can be used in the assembly and disassembly of threaded joints.

Known impact wrench, comprising a housing, a drive placed therein, an anvil spindle with a turnkey head on one end and working cams on the other, a hammer with working cams spring-loaded relative to the anvil, kinematically connected to the drive through a leash and carrier, which is fixed at the end drive output shaft, and centrifugal loads placed between the carrier and driver P1.

However, the known design is characterized by insufficient energy of a single impact and low reliability due to the phenomenon of edge impact of the cams of the striker and the anvil.

Closest to the proposed technical essence is a pneumatic impact wrench containing a housing with a handle, a pneumatic actuator placed in it, a starting device with a reversing valve and a silencer, a spindle with a turnkey head at one end and an anvil with working cams on the other, connected with a spindle with the possibility of axial movement of the intermediate roller with an end spatial cam covering the intermediate roller, a composite impact, including a pneumatic compressor connected to the output shaft a leading part installed with the possibility of joint rotation with the leading part and axial movement of the spring-loaded driven part with working cams, reciprocal cams, anvils, centrifugal loads placed between the driven and leading parts, kinematically connecting

91 hammer with a spatial end cam pusher and mechanism for synchronizing the position of the hammer cams; and anvils [2).

The design flaw lies in the complexity of the synchronization mechanism and, as a consequence of this, low reliability.

The purpose of the invention is to increase reliability.

This goal is achieved by the fact that in a pneumatic impact wrench containing a housing with a handle, a pneumatic actuator placed in it, a starting device with a reversing valve and a silencer, a spindle with a turnkey head on one, · end and an anvil with working cams on the other, connected to the spindle with the possibility of axial movement of the intermediate roller with a spatial end cam, covering the intermediate roller, a composite drummer, including a leading part connected to the output shaft of the pneumatic actuator, is installed the spring-loaded driven part with rotary cams with the driving part and axial movement with working cams, anvil reciprocal cams, centrifugal loads placed between the driven and driving parts, the pusher kinematically connecting the punch and the spatial end cam, the pusher and the synchronization mechanism of the position of the hammer and anvil cams, intermediate the roller is made with an axial stepped hole, three radial holes for the balls made opposite the holes of a larger stage, and a collar with an end stud located at the level of the radial holes 'and on opposite sides of one of them, an axial hole is made in the leading part of the hammer, on the inner surface of which there is a bore with a conical end, in the' driven part of the hammer there is a radial hole located at the level of the butt spatial cam of the intermediate roller,, the synchronization mechanism is made in the form of an intermediate roller located in the stepped hole and axially spring-loaded centering roller with with a surface in the middle part opposite to its radial from> 291 4 versts under the balls, interacting with the conical surface of the control sleeve, covering the end of the intermediate roller and installed in the leading part of the hammer with the possibility of joint rotation and relative axial movement of the sleeve having a conical end, interacting with balls of the intermediate roller, and a radial socket for the ball interacting with the surface of the bore and its conical end face of the leading part of the striker, and the pusher full in the form of a ball placed 15th in the radial hole of the driven part of the striker and having a diameter of 1.3 ~ 1.5 times smaller than the diameter of the radial hole.

In FIG. 1 depicts a pneumatic impact wrench, general Hades; in Fig. 2 - shock-pulse mechanism in the initial position of the parts, a longitudinal section; 3 - shock-impulse mechanism., When its parts are displaced under the action of centrifugal loads immediately before the transmission of the shock pulse to the tightened threaded connection, a longitudinal section; in FIG. 4 is a section _beyond AA in FIG. 2; in FIG. 5 ~ section BB in FIG. 3; in FIG. 6 is a section BB of FIG. 3.

Pneumatic impact wrench consists of a housing 1 with a handle 2, _{35 of a} pneumatic actuator 3 located in it with an output shaft 4, a starting device 5 with a reversing valve 6 and a silencer 7, a spindle 8 with a turnkey head 9 at one end and anvil 10 with working cams 11 at the other end, the intermediate roller 12 with the end spatial cam 13, covering the intermediate roller 12 of the composite firing pin, pusher 14 and synchronization mechanism, positioning of the fist cams 11 and the anvil 10.

The intermediate roller 12 is connected at one end to the spindle 8 with the possibility of axial movement and joint rotation with it, and, unlike the design of the known device, has an axial stepped hole 15 at its free end, ra, dial holes 16 for balls 17, made opposite to the hole of a larger stage , shoulder 18 with a spike 19 located at the level of radial

916291 6 holes 16 and on opposite sides of one of them.

The composite drummer includes a leading part 20 connected to the output shaft 4 of the pneumatic actuator 3, $ mounted with the possibility of joint rotation with the leading part 20 and axial movement of the spring-loaded driven part 21 with working cams 22, reciprocating working cams 11 of the anvil 10, centrifugal loads 23, located between the leading 20 and the driven 21 parts, and the plug 24 installed between the leading part 20 and centrifugal loads 23. The leading part 20 of the composite hammer is made with an axial hole 25, on the inner surface of which I’m a bore 26 with a tapered end 27. In the driven part 21 20 of the firing pin there is a radial hole 28 located at the level of the end spatial cam 13 of the intermediate roller 12. In the radial hole 28 is placed 25 pusher 14, which is made in the form of a ball, whose diameter is 1, 3 “

1.5 times smaller than the diameter of the radial hole 28.

The synchronization mechanism is made in the form of an intermediate roller 12 located in the stepped hole 15 and axially spring-loaded centering roller 29. with a taper surface 30 in the middle ₃₅ part, located opposite the radial holes 16, made in the intermediate roller 12 under the balls 17, which interact with the conical surface 30 of the centering roller 29, covering the end of the intermediate roller 12 and installed in the axial hole 25 of the driving part 20 of the hammer with the possibility of joint rotation and relative Nogo axial movement of the sleeve 31 having a tapered end 32 which cooperates with balls 17 arranged in the intermediate roller 12 and the radial slot 33 under the bead 34, which interacts with the surface of bore 26 and its tapered end 27 of the leading portion 20, the striker. The taper of the end face 32 of the sleeve 31 is greater than the taper of the surface 30 of the centering roller 29. Centrifugal loads ⁵⁵ 23 are placed in the groove 35 of the driven part 21 of the hammer and are in contact with its profile surface 36.

The ends of the yoke 24 go into the same groove 35, the same ends of the yoke 24 are covered by a sleeve 31, in which the groove 37 is formed. The axial movement of the sleeve 31 and the yoke 24 is limited by the locking ring 38, which is installed on the inner surface of the sleeve 31.

The operation of a pneumatic impact wrench is as follows.

Through the starting device 5 and the reversing valve 6, compressed air enters the pneumatic actuator 3, the rotation from its output shaft 4 is transmitted to the leading part 20 of the composite drummer, which carries along the driven part 21, and with it the centrifugal loads 23, the plug 24 and the sleeve 31 . In this case, the working cams 22 of the driven part 21 and the working cams. the tabs 11 of the anvil 10 are in a normally disengaged state.

In the process of increasing the angular velocity of the leading 20 and driven 21 parts, centrifugal loads 23 and the ball 34 under the action of centrifugal forces begin to move to the periphery, while the ball 34 falls into the bore 26 of the leading part of the hammer, and the centrifugal loads 23 begin to interact with the profile surface Zb of the groove 35 of the driven parts of the striker and a fork 24, which begins to move towards the leading part 20 of the composite striker. The driven part 21 remains stationary, since it is spring-loaded relative to the anvil 10, while the pusher 14 is located against the trailing edge of the end-face cam 13 of the intermediate roller 12.

Together with the fork 24, the intermediate roller 12 moves with balls 17, which, interacting with the conical end 32 of the sleeve 31, move it in the same direction. The joint movement of the intermediate roller 12 with the balls 17 and the sleeve 31 continues until the conical surface of the radial socket 33 abuts against the ball 34, which at this time interacts with the conical end 27 of the bore 26 of the driving part 20 of the striker.

With further acceleration of the composite impactor, centrifugal loads 23 move the fork 24 and the intermediate roller 12 with balls 17, which,

Ί 916291 8 interacting with the conical end face 32 of the sleeve 31, are pressed by the latter into the radial holes 16 and interacting with the conical surface 30 of the centering roller 29, trap it in the stepped hole 15, while the spike 19 abuts against the ball 34.

The rotation of the sleeve 31 relative to the intermediate roller 12 leads to the rotation of the balls 17 in its radial holes 16 and the centering roller 29 interacting with them, thereby reducing the friction moment.

At this moment of movement, the pusher (4 comes off the rear edge of the end spatial cam 13 of the intermediate roller 12, In the course of further axial movement of the intermediate roller 12, it overcomes the frictional force between the ball 34 and the conical end 27 of the bore 26 and presses the ball 34 into the radial socket with a spike 19 33 of the leading part 20 of the firing pin and continues to move together with the balls 17, the sleeve 31 and the plug 24 until it abuts against the end of the stepped hole 15 against the end of the taper surface 30 of the centering roller 29, which the turn rests against the end face of the driving part 20. At the same moment, the pusher 14 is located above the spatial cam 13 of the intermediate roller 12, as a result of which it becomes possible to run the pusher 14 of the spatial cam 13.

In the process of rotation of the composite firing pin, the pusher 14 is run over the profile surface of the end spatial cam 13 and, acting on the lateral surface of the radial hole 28 of the driven part 21 of the firing pin, moves it to the side; the anvil 10 along a predetermined path until the impact of the working cams 22 of the driven part 21 with the working cams 11 of the anvil 10, as a result of which the accumulated kinetic energy is transmitted to the tightened threaded connection, & the process of impact engagement of the working cams 22 and 11, respectively. Of the driven part 21 of the striker and the anvil 10, the rotating parts of the pneumatic impact wrench are completely braked, the centrifugal forces acting on the centrifugal loads 23 are stopped and the spring-loaded part 21 of the composite striker, the intermediate roller 12 together with the balls 17, the plug 24 and the sleeve 31 with the ball 34 return to their original position. Further work is repeated in the above sequence. Work in reverse mode is carried out similarly.

The absence of the edge impact of the cams is ensured by installing in a certain angular position the apex of the end spatial cam 13 of the intermediate roller 12 relative to the working cams 11 of the anvil 10.

The synchronization of the movement of the intermediate roller 12 to the final position is achieved by installing in a certain angular position a sleeve 31 with a radial socket 33 relative to the driven part 21 with a radial hole 28 for the pusher 14 and the spike 19 of the intermediate roller 12 relative to the top of its end face 36 cam. Due to the change the design of the mechanism for synchronizing the relative position of the working cams of the composite impactor and the anvil, excluding the _35th phenomenon of edge impact., and replacing the friction of the current pair increases the reliability of the pneumatic impact wrench.

Claims (1)

Claim Pneumatic impact wrench containing a housing with a handle, a pneumatic actuator placed in it, a starting device with a reversing valve and a silencer, a spindle with a turnkey head at one end and an anvil with working cams on another ₅₀ g, connected to the spindle with the possibility of axial movement of the intermediate roller with mechanical spatial cam covering intermediate 'roller integral firing pin ₅₅ includes an output shaft connected with pneumatic driving portion mounted for joint in Communication with the leading part and axial movement of the spring-loaded driven part with working cams, anvil mating cams, centrifugal weights placed between the driven and driving parts, a pusher kinematically connecting the punch and the end spatial cam, and a mechanism for synchronizing the position of the hammer and anvil cams, characterized in that that, in order to increase reliability, the intermediate roller is made with an axial stepped hole, three radial holes for balls made opposite the hole a higher step, and a shoulder with an end stud located at the level of the radial hole and on opposite sides of one of them, an axial hole is made in the leading part of the hammer, on the inner surface of which there is a bore with a conical end, a radial hole is made in the driven part of the hammer, located at the level of the end spatial cam 25 of the intermediate roller, the synchronization mechanism is made in the form of an intermediate roller located in the stepped hole and spring-loaded centered in the axial direction of the center measuring roller with a conical surface in the middle part opposite to its radial holes 5 for balls interacting with the conical surface of the control sleeve, covering the end of the gap between the precision roller and installed in the driving part of the hammer with the possibility of 10 joint rotation and relative axial movement of the sleeve having a conical end interacting with the balls of the intermediate roller and the radial socket under the ball, 15 interacting with the surface of the bore and its conical end face of the leading part of the striker, and the pusher is made in the form of a ball placed in the radial hole of the driven part 20 of the striker and having a diameter of 1.31.5 times less than the diameter of the radial hole.