CN221604064U - Grinder for lock cylinder machining - Google Patents

Abstract

The utility model relates to the technical field of lock cylinder grinding processing, in particular to a grinding machine for lock cylinder machining. The technical proposal comprises: including backplate and belt sander, install a set of belt sander of polishing on the backplate, the drive box is installed to the backplate front side, and backplate front end both sides are provided with the switching component that drives drive box horizontal slip, and every belt sander both ends all are provided with the drive pivot, and the drive pivot rotates to be connected in the backplate, installs the band pulley in the drive pivot, installs the belt sander main part between the band pulley, and drive pivot end fixing has drive gear, installs drive gear in the drive box. According to the utility model, the lock cylinder clamped by the electric chuck can be aligned with different polishing belt main bodies by utilizing the rotation of the threaded rod, and the designated polishing belt machine is started by utilizing the driving gear transmission on the driving box, so that the quick replacement is realized, the designated polishing belt machine is automatically switched to be started, and the energy conservation is facilitated.

Description

Grinder for lock cylinder machining

Technical Field

The utility model relates to the technical field of lock cylinder grinding processing, in particular to a grinding machine for lock cylinder machining.

Background

The lock cylinder processing grinder is special equipment for processing and grinding the lock cylinder, is generally used for finely processing and adjusting the lock cylinder so as to ensure the quality and performance of the lock cylinder, and can remove the unevenness and burrs on the surface of the lock cylinder, so that the lock cylinder can be inserted and rotated more smoothly.

When carrying out the abrasive machining, often need carry out the area of polishing of different mesh numbers many times, in this process, need constantly carry out equipment switching, the lock core needs to follow and tear down and fix again, cause whole work efficiency to reduce, if install a plurality of area of polishing on same equipment, usually all area of polishing need synchronous operation, however the area of polishing of work only has one of them, and then cause the wasting of resources, set up the control of independent control switch carrying out the area of polishing, then when switching over, also need synchronous manual switch operation, can not realize automatic switch.

Disclosure of utility model

The utility model aims to solve the problems in the prior art and provides a grinder for machining a lock cylinder.

The technical scheme of the utility model is as follows: the utility model provides a lock core machining grinds machine, includes backplate and belt sander, install a set of belt sander of polishing on the backplate, the drive case is installed to the backplate front side, backplate front end both sides are provided with the switching component that drives drive case horizontal slip, every belt sander both ends all are provided with the drive pivot, and drive pivot rotates to be connected in the backplate, install the band pulley in the drive pivot, install the belt sander main part between the band pulley, drive pivot end fixing has drive gear, install drive gear in the drive case, drive gear outside passes the drive case and meshes with one of them drive gear, drive incasement just passes the drive case and rotates and be connected with the spliced pole, electric chuck is installed to the spliced pole end, electric chuck aligns with one of them belt sander main part, be provided with drive component in the drive case.

Preferably, the driving assembly comprises a driving motor and a worm gear, wherein the driving motor is fixed in the driving box and aligned with the driving gear, the driving gear is fixed on the output end of the driving motor, and the worm gear is fixed at the middle position of the rotating column.

Preferably, the driving bevel gear is installed at the output end of the driving motor, a transmission rotating shaft is rotatably connected in the driving box at a position corresponding to the driving bevel gear, a transmission bevel gear meshed with the driving bevel gear is installed at the end part of the transmission rotating shaft, and a worm is fixed at a position corresponding to the worm wheel in the transmission rotating shaft.

Preferably, the switching assembly comprises a side plate, the side plate is fixed on the front side of the back plate and is aligned with the driving box in position, a group of upper end blocks are fixed on the front side of the driving box, a threaded rod is connected between the side plates in a rotating mode, the threaded rod penetrates through the upper end blocks in the middle position and is in threaded connection with the upper end blocks in the middle position, a pair of limiting rods are fixed between the side plates, and the limiting rods penetrate through the corresponding upper end blocks and are in sliding connection with the upper end blocks.

Preferably, one end of the threaded rod penetrates through the side plate and is fixedly provided with a rocker.

Preferably, the controller is installed on the side wall of the backboard, and the polishing belt main body installed on the polishing belt machine is different in specification.

Compared with the prior art, the utility model has the following beneficial technical effects: the lock core clamped by the electric chuck can be aligned with different polishing belt main bodies by utilizing the rotation of the threaded rod, and the designated polishing belt machine is started by utilizing the driving gear transmission on the driving box, so that the quick replacement is realized, and the designated polishing belt machine is automatically switched to be started, thereby being beneficial to energy saving.

Drawings

FIG. 1 is a schematic view of the front appearance structure of the present utility model;

FIG. 2 is a schematic diagram of a combined cut-away structure of the drive housing and belt sander of the present utility model;

FIG. 3 is a schematic view of the internal structure of the driving box of the present utility model;

fig. 4 is a schematic view of the bottom rear surface appearance structure of the driving box of the present utility model.

Reference numerals: 1. a back plate; 11. a controller; 2. a belt grinding machine; 21. driving the rotating shaft; 22. a belt wheel; 23. polishing the belt body; 24. a transmission gear; 3. a drive box; 31. a drive gear; 32. rotating the column; 33. an electric chuck; 34. an upper end block; 35. a threaded rod; 36. a limit rod; 37. a side plate; 38. a rocker; 4. a drive assembly; 41. a driving motor; 42. a worm wheel; 43. a transmission rotating shaft; 44. a worm; 45. a transmission bevel gear; 56. driving the bevel gear.

Detailed Description

The technical scheme of the utility model is further described below with reference to the attached drawings and specific embodiments.

Examples

As shown in fig. 1-4, the grinder for machining lock cylinders provided by the utility model comprises a back plate 1 and polishing belt machines 2, wherein a group of polishing belt machines 2 are installed on the back plate 1, a driving box 3 is installed on the front side of the back plate 1, switching components for driving the driving box 3 to horizontally slide are arranged on two sides of the front end of the back plate 1, driving rotating shafts 21 are arranged on two ends of each polishing belt machine 2, the driving rotating shafts 21 are rotatably connected in the back plate 1, belt wheels 22 are installed on the driving rotating shafts 21, polishing belt bodies 23 are installed between the belt wheels 22, transmission gears 24 are fixed at the ends of the driving rotating shafts 21, driving gears 31 are installed in the driving box 3, the outer sides of the driving gears 31 penetrate through the driving box 3 and are meshed with one of the transmission gears 24, a rotating column 32 is rotatably connected in the driving box 3, an electric chuck 33 is installed at the tail end of the rotating column 32, the electric chuck 33 is aligned with one of the polishing belt bodies 23, driving components 4 are arranged in the driving box 3, a controller 11 is installed on the side wall of the back plate 1, and the specifications of the polishing belt bodies 23 installed on different polishing belt machines 2 are different.

The driving assembly 4 comprises a driving motor 41 and a worm gear 42, the driving motor 41 is fixed in the driving box 3, the position of the driving motor is aligned with the driving gear 31, the driving gear 31 is fixed on the output end of the driving motor 41, the worm gear 42 is fixed in the middle of the rotating column 32, a driving bevel gear 56 is installed at the output end of the driving motor 41, a transmission rotating shaft 43 is rotatably connected in the driving box 3 and corresponding to the driving bevel gear 56, a transmission bevel gear 45 meshed with the driving bevel gear 56 is installed at the end of the transmission rotating shaft 43, a worm 44 is fixed on the transmission rotating shaft 43 and corresponding to the worm gear 42, the driving of the output end of the driving motor 41 is utilized to enable the driving gear 31 to rotate, and the designated driving rotating shaft 21 is driven to rotate under the transmission of the transmission gear 24, the driving bevel gear 56 is driven to rotate by the output end of the driving motor 41, the transmission rotating shaft 43 and the worm 44 are driven to rotate by the transmission bevel gear 45, and the rotating column 32 and the electric chuck 33 are driven to rotate by the transmission of the worm gear 42.

The switching assembly comprises side plates 37, wherein the side plates 37 are fixed on the front side of the back plate 1 and are aligned with the driving box 3, a group of upper end blocks 34 are fixed on the front side of the driving box 3, threaded rods 35 are rotatably connected between the side plates 37, the threaded rods 35 penetrate through the upper end blocks 34 in the middle position and are in threaded connection with the upper end blocks 34 in the middle position, a pair of limiting rods 36 are fixed between the side plates 37, the limiting rods 36 penetrate through the corresponding upper end blocks 34 and are in sliding connection with the upper end blocks 34, one end of each threaded rod 35 penetrates through the side plate 37 and is fixedly provided with a rocker 38, and when the rocker 38 drives the threaded rods 35 to rotate, the driving box 3 can horizontally slide between the side plates 37, so that the electric chuck 33 can move to be aligned with different polishing belt bodies 23.

In this embodiment, the whole device is firstly connected with an external power supply, then the lock cylinder to be ground is fixed by the electric chuck 33, the surface of the lock cylinder is connected with the polishing belt main body 23, then the drive of the output end of the drive motor 41 is utilized, so that the drive gear 31 rotates, and the designated drive rotating shaft 21 is driven to rotate under the transmission of the transmission gear 24, finally the belt pulley 22 rotates, so that the lock cylinder surface continuously slides on the surface of the polishing belt main body 23, in the process, the output end of the drive motor 41 drives the drive bevel gear 56 to rotate, the transmission of the transmission bevel gear 45 is utilized, the transmission rotating shaft 43 and the worm 44 are rotated, the transmission of the worm gear 42 is utilized, the rotating column 32 and the electric chuck 33 can be driven to rotate, finally the lock cylinder is rotated, the grinding efficiency is improved, when the threaded rod 35 is driven to rotate by the rocker 38, the drive box 3 can horizontally slide between the side plates 37, so that the lock cylinder can be moved to the alignment position with different polishing belt main bodies 23, the lock cylinder is synchronously driven to be started by different transmission gears 24 and 31, automatic switching is realized, all the polishing belt 2 are not required to be opened, and all purposes of the polishing belt 2 are realized.

The above-described embodiments are merely a few preferred embodiments of the present utility model, and many alternative modifications and combinations of the above-described embodiments will be apparent to those skilled in the art based on the technical solutions of the present utility model and the related teachings of the above-described embodiments.

Claims (6)

1. The utility model provides a lock core machining grinds machine, includes backplate (1) and belt sander (2), its characterized in that: install a set of belt sander (2) on backplate (1), drive case (3) are installed to backplate (1) front side, backplate (1) front end both sides are provided with and drive case (3) horizontally sliding's switching component, every belt sander (2) both ends all are provided with drive pivot (21), and drive pivot (21) rotate and connect in backplate (1), install band pulley (22) on drive pivot (21), install belt body (23) between band pulley (22), drive pivot (21) end fixing has drive gear (24), install drive gear (31) in drive case (3), drive gear (31) outside pass drive case (3) and mesh with one of them drive gear (24), in drive case (3) and pass drive case (3) and rotate and be connected with spliced pole (32), electric chuck (33) are installed to spliced pole (32) end, electric chuck (33) align with one of them belt body (23), drive component (4) are provided with in drive case (3).

2. A grinding machine for lock cylinder machining according to claim 1, characterized in that the drive assembly (4) comprises a drive motor (41) and a worm wheel (42), the drive motor (41) being fixed in the drive housing (3) in alignment with the drive gear (31), the drive gear (31) being fixed on the output of the drive motor (41), the worm wheel (42) being fixed in a position intermediate the rotation column (32).

3. The grinding machine for machining lock cylinders according to claim 2, wherein a driving bevel gear (56) is installed at the output end of the driving motor (41), a transmission rotating shaft (43) is rotatably connected in the driving box (3) at a position corresponding to the driving bevel gear (56), a transmission bevel gear (45) meshed with the driving bevel gear (56) is installed at the end part of the transmission rotating shaft (43), and a worm (44) is fixed on the transmission rotating shaft (43) at a position corresponding to the worm wheel (42).

4. A lock cylinder machining grinder according to claim 1, characterized in that the switching assembly comprises a sideboard (37), the sideboard (37) being fixed to the front side of the back plate (1) and being positioned in alignment with the drive box (3), a set of upper end blocks (34) being fixed to the front side of the drive box (3), threaded rods (35) being connected in rotation between the sideboard (37), the threaded rods (35) passing through the upper end blocks (34) in intermediate positions and being screwed with the upper end blocks (34) in intermediate positions, a pair of limit bars (36) being fixed between the sideboard (37), the limit bars (36) passing through the corresponding upper end blocks (34) and being slidingly connected with the upper end blocks (34).

5. A grinder for lock cylinder machining according to claim 4, characterized in that one end of the threaded rod (35) passes through the sideplate (37) and is fixed with a rocker (38).

6. A grinding machine for machining lock cylinders according to claim 1, characterized in that the side wall of the back plate (1) is provided with a controller (11), and the specifications of the grinding belt bodies (23) mounted on different grinding belt machines (2) are different.