CN212763313U - Broken screw taking-out device - Google Patents

Abstract

The utility model relates to a broken screw taking-out device, the structure of which is a simple beam structure, a load beam is supported and installed above a base through a heightening column, the heightening column is a double-thread, one end of the heightening column is screwed into the base, and the other end of the heightening column is used for matching with a hexagon nut to restrain the load beam; a threaded hole is formed in the middle of the load beam, the sliding inner guide rod penetrates through the threaded hole, a threaded outer sleeve is sleeved outside the threaded inner guide rod, the threaded outer sleeve is connected with a threaded pair of the threaded hole of the load beam, and a knurled nut is arranged on the threaded outer sleeve; the top end of the sliding inner guide rod is provided with a winch which is axially constrained by a cylindrical head socket head cap screw; the adaptive spring is arranged on one side of the sliding inner guide rod and is limited by a split pin retainer ring for a shaft; the riving knife is arranged at the tail end of the sliding inner guide rod and is tightly fixed by a flat-end inner hexagon to carry out axial and radial restraint. The advantages are that: the screw can be broken in the product threaded hole, the broken screw can be taken out under the condition that the product threaded hole is not damaged, and the threaded connection strength of the threaded hole is not influenced.

Description

Broken screw taking-out device

Technical Field

The utility model relates to a disconnected screw remove device belongs to mechanical assembly technical field.

Background

At present, a large number of screws are used for assembling parts in the electronic and mechanical assembly industry, the screws are difficult to be screwed off due to screw failure or improper pretightening force in the assembling process, and the small screws are easy to break. The common methods for taking out the broken screw mainly comprise two methods, namely electrosparking, drilling a hole in the cross section of the screw by using a drill bit, and taking out the broken screw through the hole in the cross section of the screw by using an anti-self-tapping screw tap. The former has the disadvantages that the rust-proof parts need to be disassembled separately and immersed in the processing oil, while electronic and precise mechanical products forbid the use of parts stained with the oil, and the disassembly can cause the scrapping of the parts; the latter is only suitable for large screws and not for small screws below M5.

Disclosure of Invention

The utility model provides a broken screw remove device, its aim at is not enough in order to solve above-mentioned background existence, provides a high reliable, high-efficient harmless small-size screw rupture and takes out frock and application method.

The technical solution of the utility model is as follows: a broken screw taking-out device is of a simply supported beam structure and comprises a base 1, a heightening column 2, a hexagonal nut 3, a load beam 4, a cylindrical head inner hexagonal screw 5, a winch 6, a knurled nut 7, a threaded outer sleeve 8, an adaptive spring 9, a shaft split washer 10, a flat end inner hexagonal fastening 11, a sliding inner guide rod 12 and a cleaver 13; the load beam 4 is supported and installed above the base 1 through the heightening column 2, the heightening column 2 is in double-thread shape, one end of the heightening column is screwed into the base 1, and the other end of the heightening column is used for being matched with the hexagonal nut 3 to restrain the load beam 4; a threaded hole is formed in the middle of the load beam 4, the sliding inner guide rod 12 penetrates through the threaded hole, a threaded outer sleeve 8 is sleeved outside the sliding inner guide rod, the threaded outer sleeve 8 is connected with a threaded pair of the threaded hole of the load beam, and a knurled nut 7 is arranged on the threaded pair; the top end of the sliding inner guide rod 12 is provided with a winch 6 which is axially constrained by a cylindrical head inner hexagon screw 5; the adaptive spring 9 is arranged at the lower part of the sliding inner guide rod 12 and is limited by a split pin retainer ring 10 for a shaft; the riving knife 13 is arranged at the tail end of the sliding inner guide rod 2, and the flat-end inner hexagonal fastening 11 is used for carrying out axial and radial restraint.

The winch 6 and the top end of the sliding inner guide rod 12 are assembled in a concave-convex structure.

The threaded outer sleeve 8 and the sliding inner guide rod 12 adopt a base hole H7/g6 tolerance precision.

The outer threaded sleeve 8 is rotated, the adaptive spring 9, the split retainer ring 10 for the shaft, the flat-end inner hexagonal fastener 11, the sliding inner guide rod 12 and the riving knife 13 can axially move along with the outer threaded sleeve 8.

The adaptive spring 9 is a pressure spring and always applies axial pre-tightening force to the sliding inner guide rod 12; under the action of external force, the adaptive spring 9 is continuously compressed, and the compression allowance is not less than 20 mm.

When the sliding inner guide rod 12 is subjected to the pre-tightening force of the adaptive spring 9, the winch 6 can still rotate.

The cleaver 13 is made of hard alloy and is detachably arranged at the tail end of the sliding inner guide rod 2, the geometric shape of the contact end of the cleaver and the cross section of the screw is a flat rectangle, and the length dimension is 0.3-0.8 m smaller than the width dimension of the inner diameter of the thread.

The anti-skid rubber mat 14 is further included, the anti-skid rubber mat 14 is installed on the base, and the repair part is placed on the anti-skid rubber mat 14 during working.

The utility model has the advantages that:

1) when the screw is broken in the product threaded hole, the broken screw can be taken out under the condition that the product threaded hole is not damaged, and the threaded connection strength of the threaded hole is not influenced.

2) The tool framework is of a simply supported beam structure, and the working table surface has a large operation space.

3) The broken screw is withdrawn from the threaded hole and axially displaced and acts on the sliding inner guide rod, the sliding inner guide rod is displaced and acts on the adaptive spring, the adaptive spring is continuously and elastically deformed to eliminate stress generated during the displacement of the broken screw, stress damage to the threaded hole of the repair part caused by the stress is avoided, and meanwhile, the broken screw cannot be smoothly withdrawn from the threaded hole due to the fixed position of the riving knife is avoided.

Drawings

FIG. 1 is a schematic view of a broken screw removing device.

Fig. 2 is a front view of the broken screw removing device.

Fig. 3 is a schematic view of the placement of a workpiece.

In the figure, 1-base, 2-heightening column, 3-DIN934_ M14 hexagon nut, 4-load beam, 5-DIN912_ M3 cylindrical head hexagon socket head screw, 6-winch, 7-knurled nut, 8-threaded outer sleeve, 9-adaptive spring, 10-DIN6799_ M9 shaft split retainer ring, 11-DIN913_ M3 flat end hexagon socket head fastening, 12-sliding inner guide rod and 13-cleaver.

Detailed Description

The technical scheme of the utility model is further explained by combining the attached drawings

As shown in attached figures 1 and 2, the small screw breaking and taking-out tool is high in reliability, high in efficiency and free of damage. The tool mainly comprises a base 1, a heightening column 2, a hexagon nut 3, a load beam 4, a hexagon socket screw 5, a capstan 6, a knurled nut 7, a threaded outer sleeve 8, an adaptive spring 9, a split collar 10 for a shaft, a hexagon socket fastening 11, a sliding inner guide rod 12, a cleaver 13 and an anti-slip rubber pad 14, a repaired product is placed on a working table (figure 3), the threaded outer sleeve 13 is supported against a threaded section by adjusting the threaded outer sleeve 8, the threaded outer sleeve 8 is continuously adjusted in height to enable the adaptive spring 9 to obtain adaptive pressure, the capstan 6 is rotated to enable the threaded outer sleeve 13 to drive a broken screw to rotate, and finally the broken screw is smoothly taken out.

In the scheme, the 8-threaded outer sleeve and the 12-sliding inner guide rod adopt a base hole H7/g6 to obtain better matching degree.

In the scheme, the 13-cleaver is replaceable and is fixedly fixed on the 12-sliding inner guide rod by using an 11-flat-end inner hexagon.

In the scheme, the 12-sliding inner guide rod (figure 1) is provided with a 9-adaptive spring, so that the sliding inner guide rod is relatively axially constrained under the action of the pressure of the 9-adaptive spring, and the 12-sliding inner guide rod can rotate or compress the spring to displace under the action of external force.

In the above scheme, the 6-winch is arranged at the top end of the 12-sliding inner guide rod (shown in figure 1) to facilitate the rotation of the 12-sliding inner guide rod.

In the scheme, the 4-load beam is connected with the 8-thread outer sleeve threaded pair, so that the height of the 13-cleaver and the pre-tightening force of the 9-adaptive spring can be conveniently adjusted.

In the scheme, the height of the 8-threaded outer sleeve is adjusted to enable the 13-cleaver to be in contact with the cross section of the screw, the height of the 8-threaded outer sleeve is continuously adjusted to enable the 9-adaptive spring to be pressed, and the 13-cleaver is in close contact with the cross section of the screw and is provided with a certain compression allowance under the action of the pre-tightening force of the 9-adaptive spring.

In the scheme, the 7-knurled nut is arranged on the 8-threaded outer sleeve and used for locking the 8-threaded outer sleeve.

In the scheme, the 6-capstan is rotated along the loosening direction of the screw to drive the 13-riving knife to rotate, so that the broken screw is withdrawn from the threaded hole.

In the above solution, the break-off screw is withdrawn from the threaded hole and displaced axially and acts on the 12-sliding inner guide.

In the scheme, the displacement of the 12-sliding inner guide rod acts on the 9-adaptive spring, so that the 9-adaptive spring is continuously and elastically deformed to eliminate stress generated during the displacement of the broken screw, stress damage to the threaded hole of the repaired part caused by the stress is avoided, and the situation that the broken screw cannot smoothly exit from the threaded hole due to the fixation of the 13-cleaver is avoided.

In the scheme, 14-anti-skidding rubber mats are laid on the base 1 to increase the friction coefficient with the repaired part and ensure that the repaired part cannot slide on the working table surface in the screw breaking process.

Example 1

A broken screw taking-out device is of a simply supported beam structure and comprises a base 1, a heightening column 2, a hexagonal nut 3, a load beam 4, a cylindrical head inner hexagonal screw 5, a winch 6, a knurled nut 7, a threaded outer sleeve 8, an adaptive spring 9, a shaft split washer 10, a flat end inner hexagonal fastening 11, a sliding inner guide rod 12 and a cleaver 13; the load beam 4 is supported and installed above the base 1 through the heightening column 2, the heightening column 2 is in double-thread shape, one end of the heightening column is screwed into the base 1, and the other end of the heightening column is used for being matched with the hexagonal nut 3 to restrain the load beam 4; a threaded hole is formed in the middle of the load beam 4, the sliding inner guide rod 12 penetrates through the threaded hole, a threaded outer sleeve 8 is sleeved outside the sliding inner guide rod, the threaded outer sleeve 8 is connected with a threaded pair of the threaded hole of the load beam, and a knurled nut 7 is arranged on the threaded pair; the top end of the sliding inner guide rod 12 is provided with a winch 6 which is axially constrained by a cylindrical head inner hexagon screw 5; the adaptive spring 9 is arranged on one side of the sliding inner guide rod 12 and is limited by a split pin retainer ring 10 for a shaft; the riving knife 13 is arranged at the tail end of the sliding inner guide rod 2, and the flat-end inner hexagonal fastening 11 is used for carrying out axial and radial restraint.

The model of the hexagon nut 3 is DIN934_ M14, the model of the socket head cap screw 5 is DIN912_ M3, the model of the shaft circlip 10 is DIN6799_ M9, and the model of the flat-end socket head cap tightening 11 is DIN913_ M3.

When the repairing part is used, the repairing part is placed on the surface of a workbench, the broken screw is aligned to the 13-cleaver, the 8-threaded outer sleeve is adjusted, the 13-cleaver is in contact with the broken section of the screw, the height of the 8-threaded outer sleeve is continuously adjusted, the 9-adaptive spring is pressed, the 13-cleaver is in close contact with the broken section of the repairing part screw and a certain compression allowance is reserved under the action of the pretightening force of the 9-adaptive spring, the 7-knurled nut is locked, the 6-winch is rotated along the withdrawing direction of the screw, and the screw is rotated along with the 13-cleaver until the screw hole is.

Claims (9)

1. A broken screw taking-out device is characterized by being of a simply supported beam structure and comprising a base (1), a heightening column (2), a hexagonal nut (3), a load beam (4), a cylindrical head inner hexagonal screw (5), a winch (6), a knurled nut (7), a threaded outer sleeve (8), an adaptive spring (9), a shaft split washer (10), a flat end inner hexagonal fastening block (11), a sliding inner guide rod (12) and a cleaver (13); the load beam (4) is supported and installed above the base (1) through the heightening column (2), the heightening column (2) is in a double-thread shape, one end of the heightening column is screwed into the base (1), and the other end of the heightening column is used for being matched with the hexagonal nut (3) to restrain the load beam (4); a threaded hole is formed in the middle of the load beam (4), the sliding inner guide rod (12) penetrates through the threaded hole, a threaded outer sleeve (8) is sleeved outside the threaded inner guide rod, the threaded outer sleeve (8) is connected with a threaded pair of the threaded hole of the load beam, and a knurled nut (7) is arranged on the threaded outer sleeve; the top end of the sliding inner guide rod (12) is provided with a winch (6) which is axially constrained by a cylindrical head inner hexagonal screw (5); the adaptive spring (9) is arranged at the lower part of the sliding inner guide rod (12) and is limited by a split retainer ring (10) for a shaft; the cleaver (13) is arranged at the tail end of the sliding inner guide rod (12) and is axially and radially constrained by a flat-end inner hexagonal fastening (11).

2. A broken screw extraction device according to claim 1, characterised in that the capstan (6) is fitted with the top end of the sliding inner guide rod (12) in a concavo-convex configuration.

3. A broken screw extraction device according to claim 1, characterised in that the threaded outer sleeve (8) and the sliding inner guide (12) adopt a base hole system H7/g6 tolerance accuracy.

4. A broken screw extraction device as claimed in claim 1, 2 or 3, wherein the threaded outer sleeve (8) is rotated, the adapter spring (9), the split collar (10) for the shaft, the flat end socket head (11), the sliding inner guide rod (12) and the riving knife (13) are axially movable with the threaded outer sleeve (8).

5. A broken screw extraction device according to claim 1, 2 or 3, wherein the adapter spring (9) is a compression spring which always exerts an axial pretension on the sliding inner guide rod (12).

6. A broken screw extraction device according to claim 5, wherein under the action of the axial pre-load force, the adaptive spring (9) will continue to compress by a margin of not less than 20 mm.

7. A broken screw extraction device according to claim 1, 2 or 3, characterised in that the capstan (6) is rotatable when the sliding inner guide rod (12) is subjected to the pre-load of the adaptive spring (9).

8. The broken screw extraction device according to claim 1, wherein the riving knife (13) is made of hard alloy, is detachably mounted at the tail end of the sliding inner guide rod (12), and is flat and rectangular in geometry of a contact end with the cross section of the screw, and the length dimension is smaller than the width dimension of the inner diameter of the thread by 0.3-0.8 m.

9. A broken screw extraction device according to claim 1 further comprising an anti-slip rubber pad (14), the anti-slip rubber pad (14) being mounted on the base and the repair member being placed on the anti-slip rubber pad (14) during operation.

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