RU220053U1 - MECHANICAL PULLER - Google Patents

Abstract

The utility model relates to the field of mechanical engineering, in particular to devices for dismantling parts, mainly a press connection, for example, for removing gears, pulleys, bearings from shafts. SUBSTANCE: mechanical puller contains a traverse with grippers, a power screw made with two external threads of different pitches relative to each other in the same direction, a threaded main bushing installed on the thread of a smaller pitch of the power screw, a threaded additional bushing installed on the second thread of the power screw, and a clip covering both bushings, fixed relative to the latter in the angular direction, resting on the main bushing with an internal shoulder, made on one end of the cage, and with the other open end installed in the through hole of the traverse and rigidly connected to the latter, differs in that an external thread is made on the additional bushing, on which is a flat nut that performs the function of a movable flange. The technical result is the creation of a mechanical puller design that allows expanding the range of serviced units and providing traction control. 1 ill.

Description

The utility model relates to the field of mechanical engineering, in particular to devices for dismantling parts, mainly a press connection, for example, for removing gears, pulleys, bearings from shafts.

A mechanical puller is known (patent RU No. 990493, IPC V25V 27/02, publ. 01/23/1983), containing a traverse, grips associated with the traverse, and a sleeve having an external thread associated with the traverse thread, and an internal thread associated with a power screw. The outer thread of the bushing is smaller than the pitch and in the opposite direction relative to its inner thread. And at the upper end of the power screw, a drive element is installed with the possibility of axial movement, at the end of which protrusions are made to interact with the grooves made at the end of the bushing. At the same time, at the other end of the sleeve, an outer flange is made, which rests on the traverse.

A disadvantage of the known puller is the need to increase the thrust of removing the part to articulate the drive element with the sleeve and change the direction of rotation of the power screw, which is an inconvenience of operation.

A mechanical puller is known (patent RU No. 2009869, IPC V25V 27/02, publ. 03/30/1994), containing a traverse with grippers, a power screw made with two external threads of different pitches and directions relative to each other, and two threaded bushings - the main one, installed on the screw thread with a smaller pitch, and an additional one installed on the second screw thread. The bushings are covered by a cage resting on the main bushing with an internal shoulder made at one end of the cage, and the cage is installed in the through hole of the traverse with the other open end and is rigidly connected to the latter. The glass and the bushing are fixed relative to each other in the angular direction by means of radial pins fixed on the bushings and placed in the longitudinal groove of the holder. The cage groove has an L-shaped end for interaction with the transverse section with the radial pin of the additional bushing during the transition from the initial stage of removal of the part to the final one.

A disadvantage of the known puller is the need to change the direction of rotation of the power screw at the end of the initial stage of removing the part, which in itself is inconvenient, and, in addition, leads to a lateral displacement of the puller relative to the part, since the axial tightness between them is weakened, which requires restoring their mutual centering .

The closest technical solution is a mechanical puller. (patent RU No. 2271922, IPC V25V 27/02, V23R 19/02, publ. 03/20/2006), containing a traverse with grippers, a power screw made with two external threads in the same direction, but of different pitches relative to each other, a threaded main sleeve , installed on the thread of a smaller pitch of the power screw, a threaded additional bushing installed on the second thread of the power screw, and a cage covering both bushings, fixed relative to the latter in the angular direction, resting on the main bushing with an internal shoulder made on one end of the cage, and the other open end installed in the through hole of the traverse and rigidly connected to the latter. An outer flange is made on the additional bushing, which opposes the open end of the cage with a certain interval.

The disadvantage of this puller is a narrow scope due to the constant value of the gap between the outer flange of the additional bushing and the open end of the cage, which does not allow taking into account the difference in the stroke of the removed part, due to the design of the assembly on which any element is removed using the puller.

The technical result of the proposed utility model is the creation of a mechanical puller design that makes it possible to expand the range of serviced units and increase the convenience of setting up and operating the puller.

The technical result is achieved by the fact that a mechanical puller containing a traverse with grips, a power screw made with two external threads of different pitches relative to each other in the same direction, a threaded main sleeve mounted on a thread of a smaller pitch of the power screw, a threaded additional sleeve mounted on the second thread power screw, and a cage, covering both bushings, fixed relative to the latter in the angular direction, resting on the main bushing with an internal shoulder made on one end of the cage, and with the other open end installed in the through hole of the traverse and rigidly connected to the latter, differs in that on the additional bushing has an external thread, on which a flat nut is located, which acts as a movable flange.

The presence of an external thread on the additional sleeve allows you to move the nut along it, which provides the nut with the function of a movable flange. This design allows you to adjust the gap between the flat nut and the open end of the cage in a wide range, depending on the intended stroke of the removed part, providing different pulling force of the puller in the initial and final stages of removing the part. In some cases, tight connections require a constant removal force, in this situation the nut can be removed from the additional sleeve, and the puller will work in the mode of constant initial maximum thrust when removing the part.

The free movement of the flat nut along the external thread of the additional sleeve increases the convenience of setting when operating a mechanical puller.

All of the above in the proposed design of the mechanical puller makes it possible to expand the range of serviced units and increase the convenience of setting up and operating the puller.

The drawing shows a longitudinal section of a mechanical puller in its original working position.

The mechanical puller contains a traverse 1 with grippers 2, a power screw 3, made with two external threads of different pitches relative to each other in the same direction, while the main bushing 5 is installed on the smaller pitch thread 4, and the additional bushing 7 is installed on the larger pitch thread 6. Bushings 6 and 7 covers the clip 8 with a shoulder, fixed relative to the latter in the angular direction by the keys 9 and 10. On the main sleeve 5, the clip 8 is supported by an internal shoulder, made on one end of the clip, and the other open end of the clip 8 is installed in the through hole of the traverse 1 and rigidly connected to the latter by means of a fixed threaded connection. An external thread is made on the additional sleeve 7, on which a flat nut 11 is located, which opposes the open end of the cage 8. Free movement of the flat nut 11 along the external thread of the additional sleeve 7 allows you to adjust the gap between the flat nut and the open end of the cage 8 in a wide range. Between the bushings 5 and 7, an interval is formed that is larger than the amount of convergence of the bushings.

The mechanical puller works as follows.

During the rotation of the power screw 3, which rests on the shaft 12, with the grips 2 installed on the part 13, the main sleeve 5, resting on the shoulder of the holder 8, creates thrust at the initial stage of removing the part 13 from the shaft 12. When the part 13 is shifted, the additional sleeve 7 will sink into the holder 8 to a depth due to the difference between the axial stroke of the sleeve 7 along the power screw 3 and its stroke together with the power screw. When the gap between the flat nut 7 and the open end of the cage 8 is exhausted, resting with the flat nut 7 on the open end of the cage 8, the additional bushing 7 will smoothly take over the thrust of the final stage of removing the part 13, unloading the main bushing 5, which will begin to separate from the shoulder of the cage 8 As a result of removing part 13, bushings 5 and 7 will mutually approach each other, while the interval between the bushings is greater (almost by 2-3 mm) than the mutual convergence of bushings 5 and 7 excludes their mutual locking on the power screw 3 when removing part 13. With the same force on the handle of power screw 3, the puller force in the initial stage of removing part 13 will be higher than its traction force in the final stage in a ratio equal to the ratio of thread pitches 6 of additional sleeve 7 and thread 4 of main sleeve 5. Despite the fact that the amount of shift of part 13 on the shaft 12 with increased thrust will be less, the reliability of the dismantling of the part will be ensured, since a significantly increased force of the press joint connector is observed in the initial stage, constituting a smaller proportion of the joint. The free movement of the flat nut 11 along the external thread of the additional sleeve 7 allows you to adjust the gap between the flat nut and the open end of the cage 8 in a wide range, this allows you to vary the amount of shift of the part 13 on the shaft 12 in a wide range with increased thrust.

Thus, the proposed design of the mechanical puller allows you to expand the range of serviced units and increase the convenience of setting up and operating the puller.

Claims (1)

A mechanical puller containing a traverse with grippers, a power screw made with two external threads of different pitches relative to each other in the same direction, a threaded main bushing mounted on the thread of a smaller pitch of the power screw, a threaded additional bushing mounted on the second thread of the power screw, and a holder, enclosing both bushings, fixed relative to the latter in the angular direction, resting on the main bushing with an internal shoulder made at one end of the cage, and with the other open end installed in the through hole of the traverse and rigidly connected to the latter, characterized in that the additional bushing has an external thread, on which a flat nut is located, which acts as a movable flange.

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