CN220095264U - Magnetic lock body processing equipment - Google Patents

Abstract

The utility model discloses a magnetic lock body processing device which comprises a machine base, a first cutting mechanism, a first driving mechanism, a clamping mechanism and a grooving mechanism. The machine base is provided with a first workpiece guide groove along the left-right direction, and the first workpiece guide groove is provided with a first entering end and a first moving-out end; the first cutting mechanism is arranged on the base and positioned on the side wall of the first workpiece guide groove; the first driving mechanism is arranged on the base and used for driving the workpiece to move along the first workpiece guide groove; the clamping mechanism is arranged on the machine base and used for clamping or loosening a workpiece, and is provided with a workpiece clamping position which is in butt joint with the first moving-out end of the first workpiece guide groove; the grooving mechanism is arranged on the machine base and is used for cutting an installation groove on a workpiece on the workpiece clamping position. The magnetic lock body processing equipment can further improve the automation degree in the production process of the magnetic lock body.

Description

Magnetic lock body processing equipment

Technical Field

The utility model relates to the field of magnetic lock processing, in particular to magnetic lock body processing equipment.

Background

When the magnetic lock is manufactured, the magnetic lock body is required to be used, when the magnetic lock body is produced, the outer side of the magnet is required to be subjected to injection molding and encapsulation into a cuboid shape by using a mold, then a manufacturer uses a tool to remove injection molding flash of the magnetic lock body, and then the magnetic lock body is fixed on an existing grooving machine to cut an installation groove, and the installation groove can be used for installing a Hall element after cutting. However, after injection molding is completed, the production process of removing burrs and cutting the mounting groove of the magnetic lock body still needs high participation of production personnel, and the degree of automation still has room for improvement.

Disclosure of Invention

The present utility model aims to solve at least one of the technical problems existing in the prior art. Therefore, the utility model provides the magnetic lock body processing equipment, which can further improve the automation degree in the production process of the magnetic lock body.

The processing equipment for the magnetic lock body comprises a base, a first cutting mechanism, a first driving mechanism, a clamping mechanism and a grooving mechanism. The machine base is provided with a first workpiece guide groove along the left-right direction, and the first workpiece guide groove is provided with a first entering end and a first moving-out end; the first cutting mechanism is arranged on the base and positioned on the side wall of the first workpiece guide groove; the first driving mechanism is arranged on the base and used for driving the workpiece to move along the first workpiece guide groove; the clamping mechanism is arranged on the machine base and used for clamping or loosening a workpiece, and is provided with a workpiece clamping position which is in butt joint with the first moving-out end of the first workpiece guide groove; the grooving mechanism is arranged on the machine base and is used for cutting the mounting groove on the workpiece clamping position.

The magnetic lock body processing equipment provided by the embodiment of the utility model has at least the following beneficial effects: the magnetic lock body after injection molding is sent into the first workpiece guide groove from the first inlet end, then the first driving mechanism pushes the workpiece to move along the first workpiece guide groove, the first cutting mechanism positioned on the side wall of the first workpiece guide groove removes burrs on the workpiece in the workpiece moving process, then the workpiece enters the workpiece clamping position, the clamping mechanism clamps and fixes the workpiece, the grooving mechanism feeds to cut an installation groove for installing the Hall element on the workpiece, and then the clamping mechanism loosens the workpiece. The magnetic lock body processing equipment can further improve the automation degree in the production process of the magnetic lock body.

According to some embodiments of the utility model, two first cutting mechanisms are provided, and the two first cutting mechanisms are respectively located on two side groove walls of the first workpiece guiding groove.

According to some embodiments of the utility model, the first cutting mechanism comprises a milling cutter and a cutting edge driver, wherein the cutting edge driver is connected with the base, and is connected with the milling cutter and can drive the milling cutter to rotate, and the milling cutter is positioned on the side wall of the first workpiece guide groove.

According to some embodiments of the utility model, the clamping mechanism comprises a clamping mounting seat, a first clamping block, a second clamping block and a clamping driver, the first clamping block is connected with the base, the clamping mounting seat is connected with the base, the first clamping block and the second clamping block are distributed at intervals front and back, the second clamping block is movably arranged on the clamping mounting seat, the moving direction of the second clamping block is obliquely arranged relative to the horizontal direction, the clamping driver is arranged on the clamping mounting seat and is used for driving the second clamping block to be close to or far away from the first clamping block, the workpiece clamping position is located between the first clamping block and the second clamping block, and a workpiece adapting groove is formed in one side of the second clamping block, which is close to the first clamping block.

According to some embodiments of the utility model, the first driving mechanism comprises a side-moving driver, a side-moving mounting seat, a lifting driver and a pushing piece, wherein the side-moving driver is connected with the side-moving mounting seat and is used for driving the side-moving mounting seat to move left and right, the pushing piece is arranged on the side-moving mounting seat in a vertical sliding manner, the lifting driver is arranged on the side-moving mounting seat, the lifting driver is connected with the pushing piece and is used for driving the pushing piece to move vertically, the pushing piece is positioned above the first workpiece guide groove, and a limiting convex part for abutting against the side wall of the workpiece is arranged downwards.

According to some embodiments of the utility model, the workpiece clamping device further comprises an ejection mechanism, the ejection mechanism is arranged on the base, a second workpiece guide groove is arranged on the base along the front-rear direction, the second workpiece guide groove is provided with a second inlet end and a second outlet end, the second inlet end of the second workpiece guide groove is in butt joint with the workpiece clamping position, and the ejection mechanism is used for pushing a workpiece to enter the second workpiece guide groove and move along the second workpiece guide groove.

According to some embodiments of the utility model, the workpiece guide groove further comprises a second trimming mechanism, wherein the second trimming mechanism is arranged on the base, the groove wall heights of the left side and the right side of the second workpiece guide groove are different, and the second trimming mechanism is positioned on the side wall of the relatively higher side of the second workpiece guide groove.

According to some embodiments of the utility model, the feeding conveyor belt is arranged on the base in a front-rear extending manner, and is provided with a third inlet end and a third outlet end along the conveying direction, and the third outlet end is in butt joint with the first inlet end.

According to some embodiments of the utility model, the grooving mechanism comprises a feeding driver, a feeding mounting seat, a cutting driver and a grooving saw blade, wherein the feeding mounting seat is connected with the machine seat in a sliding manner along the left-right direction, the feeding driver is connected with the feeding mounting seat and used for driving the feeding mounting seat to move left and right, the cutting driver is arranged on the feeding mounting seat, the cutting driver is connected with the grooving saw blade and used for driving the grooving saw blade to rotate, and the grooving saw blade is opposite to the workpiece clamping position left and right.

According to some embodiments of the utility model, the cutting saw blade further comprises a suction mechanism, the suction mechanism is arranged on the base, the suction mechanism comprises a protective cover and a connecting pipe, the protective cover is sleeved on the outer side of the cutting saw blade, the protective cover is provided with an air passing hole, and one end of the connecting pipe is connected with the air passing hole.

Additional aspects and advantages of the utility model will be set forth in part in the description which follows, and in part will be obvious from the description, or may be learned by practice of the utility model.

Drawings

The foregoing and/or additional aspects and advantages of the utility model will become apparent and may be better understood from the following description of embodiments taken in conjunction with the accompanying drawings in which:

FIG. 1 is a schematic perspective view of a magnetic lock body processing apparatus according to an embodiment of the present utility model;

FIG. 2 is a schematic perspective view of a magnetic lock body processing apparatus according to an embodiment of the present utility model with a portion of the structure removed;

FIG. 3 is an enlarged schematic view of a portion of the magnetic lock body processing apparatus A of the embodiment of the present utility model shown in FIG. 2;

FIG. 4 is a schematic rear view of a magnetic lock body processing apparatus according to an embodiment of the present utility model with a portion of the structure removed;

FIG. 5 is an enlarged schematic view of a portion B of the magnetic lock body processing apparatus of the embodiment of the present utility model shown in FIG. 4;

FIG. 6 is a schematic perspective view of a magnetic lock body processing apparatus according to an embodiment of the present utility model with a portion of the structure removed;

FIG. 7 is a schematic perspective view of a pushing member of a magnetic lock body processing apparatus according to an embodiment of the present utility model;

fig. 8 is a schematic perspective view of a second clamping block of the magnetic lock body processing device according to the embodiment of the utility model.

Reference numerals:

a workpiece 10;

a base 100, a first workpiece guide groove 110, a second workpiece guide groove 120, a first barrier rib 130, a second barrier rib 140, and a lead arrangement groove 150;

a first cutting mechanism 200;

the device comprises a first driving mechanism 300, a side-shifting driver 310, a side-shifting mounting seat 320, a lifting driver 330, a pushing piece 340 and a limiting convex part 341;

the clamping mechanism 400 clamps the mounting seat 410, the limiting strip 411, the first clamping block 420, the second clamping block 430, the workpiece adapting groove 431 and the clamping driver 440;

a cutting mechanism 500, a feed drive 510, a feed mount 520, a cutting drive 530, and a cutting blade 540;

a push-out mechanism 600, a push frame 610, and a push-out driver 620;

a second trimming mechanism 700;

a loading conveyor 800;

suction mechanism 900, boot 910, connecting tube 920.

Detailed Description

Embodiments of the present utility model are described in detail below, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to like or similar elements or elements having like or similar functions throughout. The embodiments described below by referring to the drawings are illustrative only and are not to be construed as limiting the utility model.

In the description of the present utility model, it should be understood that the direction or positional relationship indicated with respect to the description of the orientation, such as up, down, etc., is based on the direction or positional relationship shown in the drawings, is merely for convenience of describing the present utility model and simplifying the description, and does not indicate or imply that the apparatus or element referred to must have a specific orientation, be constructed and operated in a specific orientation, and thus should not be construed as limiting the present utility model.

In the description of the present utility model, plural means two or more. The description of the first and second is for the purpose of distinguishing between technical features only and should not be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated or implicitly indicating the precedence of the technical features indicated.

In the description of the present utility model, unless explicitly defined otherwise, terms such as arrangement, installation, connection, etc. should be construed broadly and the specific meaning of the terms in the present utility model can be reasonably determined by a person skilled in the art in combination with the specific contents of the technical scheme.

When the magnetic lock is manufactured, the magnetic lock body is required to be used, when the magnetic lock body is produced, the outer side of the magnet is required to be subjected to injection molding and encapsulation into a cuboid shape by using a mold, then a manufacturer uses a tool to remove injection molding flash of the magnetic lock body, and then the magnetic lock body is fixed on an existing grooving machine to cut an installation groove, and the installation groove can be used for installing a Hall element after cutting. However, after injection molding is completed, the magnetic lock body requires a manufacturer to manually remove burrs, and carry the magnetic lock body to a grooving machine, clamp the magnetic lock body with a vice, and then manually operate the grooving machine by the manufacturer to cut an installation groove in the magnetic lock body. In the process, production personnel are required to participate in the process, and the degree of automation still has room for improvement.

Referring to fig. 1 to 8, a magnetic lock body processing apparatus according to an embodiment of the present utility model includes a base 100, a first cutting mechanism 200, a first driving mechanism 300, a clamping mechanism 400, and a grooving mechanism 500. The machine base 100 is provided with a first workpiece guide groove 110 along the left-right direction, and the first workpiece guide groove 110 is provided with a first inlet end and a first outlet end; the first cutting mechanism 200 is disposed on the base 100 and located on a side wall of the first workpiece guiding slot 110; the first driving mechanism 300 is disposed on the base 100 and is used for driving the workpiece to move along the first workpiece guiding slot 110; the clamping mechanism 400 is disposed on the stand 100 and is used for clamping or loosening a workpiece, the clamping mechanism 400 has a workpiece clamping position, and the workpiece clamping position is in butt joint with the first moving-out end of the first workpiece guiding groove 110; the grooving mechanism 500 is disposed on the stand 100 and is used for cutting a mounting groove on a workpiece at a workpiece clamping position.

The magnetic lock body after injection molding is fed into the first workpiece guide groove 110 from the first inlet end, then the first driving mechanism 300 pushes the workpiece to move along the first workpiece guide groove 110, the first cutting mechanism 200 positioned on the side wall of the first workpiece guide groove 110 removes burrs from the workpiece in the workpiece moving process, then the workpiece enters the workpiece clamping position, the clamping mechanism 400 clamps and fixes the workpiece, the grooving mechanism 500 feeds to cut a mounting groove for mounting the hall element on the workpiece, and then the clamping mechanism 400 loosens the workpiece. The magnetic lock body processing equipment can further improve the automation degree in the production process of the magnetic lock body.

In the embodiment, two first cutting mechanisms 200 are provided, and the two first cutting mechanisms 200 are respectively located on two side groove walls of the first workpiece guiding groove 110. When the first driving mechanism 300 drives the workpiece to move along the first workpiece guide groove 110, the two first cutting mechanisms 200 respectively cut and flash the front and rear side walls of the workpiece, and the cutting and flashing operation on the front and rear side walls of the workpiece can be completed only once, so that the machining efficiency is good, and the quality of the workpiece is improved.

In an embodiment, the first cutting mechanism 200 includes a milling cutter and a cutting edge driver, the cutting edge driver is connected with the machine base 100, and the cutting edge driver is connected with the milling cutter and can drive the milling cutter to rotate, and the milling cutter is located on the side wall of the first workpiece guiding slot 110. The first trimming mechanism 200 has the advantages of simple structure, convenient installation and good processing effect. Specifically, the side cut driver is the motor, and the output shaft of motor is provided with the connecting hole, and in the connecting hole was installed to the one end of milling cutter, milling cutter along vertical setting. The milling cutter cuts the side surface of the workpiece as the workpiece moves past the milling cutter along the first workpiece guide groove 110, removing burrs. It is conceivable that the trimming drive could also be an internal combustion engine or the like.

It is conceivable that the first cutting mechanism 200 may have other structures, for example, the first cutting mechanism 200 is a rotary saw blade and a motor, and an output shaft of the motor drives the rotary saw blade to rotate, the rotary saw blade is disposed parallel to a side wall of the first workpiece guiding slot 110, and the rotary saw blade can cut burrs of the workpiece, thereby removing the burrs of the workpiece.

Specifically, the workpiece slides in the first workpiece guiding groove 110, and the first driving mechanism 300 pushes the workpiece to slide along the first workpiece guiding groove 110.

Specifically, the stand 100 is provided with a flat plate and two first blocking strips 130 which are mounted on the flat plate and are distributed front and back, the first blocking strips 130 extend along the left-right direction, and the flat plate and the two first blocking strips 130 enclose to form a first workpiece guide groove 110. The above-described structure forms the first workpiece guide groove 110, and is simple in structure and easy to implement. It is conceivable to cut the first workpiece guide groove 110 in a flat plate.

In an embodiment, the clamping mechanism 400 includes a clamping mount 410, a first clamping block 420, a second clamping block 430 and a clamping driver 440, the first clamping block 420 is connected to the machine base 100, the clamping mount 410 is connected to the machine base 100, the first clamping block 420 and the second clamping block 430 are distributed at intervals front and back, the second clamping block 430 is movably arranged on the clamping mount 410, the moving direction of the second clamping block 430 is inclined relative to the horizontal direction, the clamping driver 440 is arranged on the clamping mount 410 and is used for driving the second clamping block 430 to be close to or far away from the first clamping block 420, the workpiece clamping position is located between the first clamping block 420 and the second clamping block 430, and a workpiece adapting groove 431 is formed in one side, close to the first clamping block 420, of the second clamping block 430.

The second clamping block 430 is provided with a workpiece adapting groove 431, and when the clamping driver 440 drives the second clamping block 430 to clamp the workpiece with the first clamping block 420, the workpiece adapting groove 431 is abutted to the outer side of the workpiece, and as the moving direction of the second clamping block 430 is obliquely arranged, the second clamping block 430 simultaneously applies to the vertical pressure and the clamping force in the front-back direction of the workpiece, so that the workpiece is less prone to shaking, and the stability of the clamping mechanism 400 for clamping the workpiece is improved. Specifically, the first clamping block 420 is fixed to the base by a screw, and the clamping driver 440 is an air cylinder; the second clamping block 430 is provided with a guide pillar, the clamping mounting seat 410 is provided with a guide hole, the hole axis of the guide hole is obliquely arranged, and the guide pillar is connected to the guide hole in a sliding manner, so that the second clamping block 430 is connected to the clamping mounting seat 410 in a sliding manner, and a cylinder rod of a cylinder is connected with the second clamping block 430 to drive the second clamping block 430 to move. It is conceivable that a sliding strip is further provided on the second clamping block 430, and a sliding groove is provided on the clamping mount 410, where the sliding strip is slidably connected to the sliding groove, so as to implement that the second clamping block 430 is movable relative to the clamping mount 410. The clamping driver 440 may also have a structure that outputs linear power, such as a linear motor, an electric cylinder, or an oil cylinder, and the linear motor is connected to the second clamping block 430.

It is envisioned that the clamping mechanism 400 may have other configurations, for example, the clamping mechanism 400 may employ a jaw cylinder that clamps a workpiece; or the clamping mechanism 400 may employ a robotic arm; or the clamping mechanism 400 can adopt two clamping blocks and two air cylinders, each air cylinder drives one clamping block to move, the two clamping blocks can be close to each other and far away from each other, and the two clamping blocks can clamp a workpiece when being close to each other. In the mechanical field, there are many structures for holding a certain member, and those skilled in the art can specifically configure the structure according to actual needs.

In an embodiment, the first driving mechanism 300 includes a side-shift driver 310, a side-shift mounting seat 320, a lifting driver 330, and a pushing member 340, where the side-shift driver 310 is connected with the side-shift mounting seat 320 and is used for driving the side-shift mounting seat 320 to move left and right, the pushing member 340 is arranged on the side-shift mounting seat 320 in a vertical sliding manner, the lifting driver 330 is arranged on the side-shift mounting seat 320, the lifting driver 330 is connected with the pushing member 340 and is used for driving the pushing member 340 to move vertically, the pushing member 340 is located above the first workpiece guiding groove 110, and the pushing member 340 is provided with a limiting protrusion 341 downward for abutting against a sidewall of the workpiece. The lifting driver 330 may drive the pushing member 340 to descend until the limiting protrusion 341 of the pushing member 340 abuts against the left and right sidewalls of the workpiece, and then the side shift driver 310 drives the side shift mounting seat 320 to move left and right, so as to drive the workpiece to move along the first workpiece guiding slot 110. After pushing the workpiece out of the first workpiece guide slot 110, the lifting driver 330 drives the pushing member 340 to lift off the workpiece, and the side shift driver 310 drives the side shift mounting seat 320 to reset, so that the first driving mechanism 300 resets, and then the next workpiece can be repeatedly transported. The first driving mechanism 300 has a simple and efficient structure.

Specifically, the side-shifting driver 310 may adopt a structure of outputting linear power, such as a linear motor, a cylinder, an electric cylinder, and an oil cylinder, or a structure of arranging a screw and a screw nut with the motor, wherein the screw nut is installed on the side-shifting installation seat 320, and the motor drives the screw to rotate, and the screw is arranged through the screw nut; or the motor drives the roller to rotate, and the roller rotates to be arranged on the side-shifting installation seat 320, so that the side-shifting installation seat 320 is driven to move left and right; in the field of machine tools, there are many structures for outputting linear power, and those skilled in the art can specifically configure the structure according to actual needs.

The pushing element 340 is vertically provided with a guide pillar, the side-moving installation seat 320 is provided with a guide hole, and the guide pillar is slidably connected to the guide hole, so that the pushing element 340 can vertically slide relative to the side-moving installation seat 320. The lifting driver 330 is a cylinder, and a piston rod of the cylinder is connected to the pushing member 340. It is conceivable that a sliding strip is vertically arranged on the pushing element 340, a sliding groove is arranged on the side-moving installation seat 320, and the sliding strip is slidably connected to the sliding groove, so that the pushing element 340 can vertically slide relative to the side-moving installation seat 320; the lifting driver 330 may also be a linear motor, where the linear motor drives the pushing member 340 to vertically lift.

Specifically, two limiting protruding portions 341 are provided, and two limiting protruding portions 341 are arranged at left and right intervals, so that the two side walls of the workpiece can be conveniently abutted, and the workpiece can be stably pushed to move along the first workpiece guide groove 110, and meanwhile the workpiece is not easy to vibrate when passing through the first cutting mechanism 200.

It is envisioned that the first drive mechanism 300 may also be other structures, for example, the first drive mechanism 300 may be a multi-axis robotic arm.

In an embodiment, the workpiece pushing device further includes a pushing mechanism 600, the pushing mechanism 600 is disposed on the stand 100, the stand 100 is provided with a second workpiece guiding slot 120 along the front-rear direction, the second workpiece guiding slot 120 has a second entry end and a second removal end, the second entry end of the second workpiece guiding slot 120 is opposite to the workpiece clamping position, and the pushing mechanism 600 is used for pushing the workpiece into the second workpiece guiding slot 120 and moving along the second workpiece guiding slot 120. The push-out mechanism 600 is provided, so that the workpiece can be automatically transferred to the next process after the workpiece is machined. After the clamping mechanism 400 releases the workpiece, the pushing mechanism 600 pushes the workpiece to enter the second workpiece guiding groove 120 from the second entering end, the workpiece moves along the second workpiece guiding groove 120, and then the workpiece is sent to the next process from the second moving-out end, so that the structure is simple and easy to implement. In particular, since the second clamping block 430 is moved obliquely, the second clamping block 430 may be moved to be entirely higher than the workpiece, and then the workpiece may be moved over the second clamping block 430 and along the second workpiece guide groove 120.

Specifically, the second clamping block 430 is located in front of the first clamping block 420, and the second workpiece guide slot 120 is located in front of the workpiece clamping position.

In an embodiment, the pushing mechanism 600 includes a pushing frame 610 and a pushing driver 620, the pushing driver 620 is connected to the base, and the pushing driver 620 is connected to the pushing frame 610 and is used for driving the pushing frame 610 to move in the front-back direction, so that the pushing frame 610 can push the workpiece to slide along the second workpiece guiding groove 120, and the structure is simple and easy to implement. Specifically, the push-out driver 620 may adopt a linear motor, an air cylinder, or a motor, a screw rod, a screw nut, and a roller, where the roller is rotationally connected to the push frame 610, so as to implement forward and backward movement of the push frame 610; in the field of machine tools, there are many structures for outputting linear power, and those skilled in the art can specifically configure the structure according to actual needs.

The pushing frame 610 is provided with a push rod, the first clamping block 420 is provided with a yielding hole, the push rod is arranged in the yielding hole in a penetrating way, and the push rod is used for pushing the workpiece. It is envisioned that the pusher 610 may also be a block that directly abuts the pushing work piece for movement.

It is envisioned that the ejector mechanism 600 may also be other structures, for example, the ejector mechanism 600 may be a multi-axis robot that holds a workpiece for movement along the second workpiece guide slot 120.

Specifically, the stand 100 is provided with a flat plate and two second barrier strips 140, the two second barrier strips 140 are arranged at left and right intervals, the second barrier strips 140 extend along the front and rear directions, and the two second barrier strips 140 and the flat plate form the second workpiece guide groove 120.

The heights of the two second barrier strips 140 are different, and one side of the second barrier strip 140 with a lower height can be used for yielding the lead wire extending out of the side wall of the magnetic lock body.

In an embodiment, the second trimming mechanism 700 is further included, the second trimming mechanism 700 is disposed on the stand 100, the groove wall heights of the left and right sides of the second workpiece guiding groove 120 are different, and the second trimming mechanism 700 is located on the side wall of the relatively higher side of the second workpiece guiding groove 120. The second trimming mechanism 700 described above can remove flash from the side wall of the magnetic lock body opposite the lead. The first trimming mechanism 200 is matched with the second trimming mechanism 700, so that the three side walls of the workpiece are all subjected to the deburring processing. Specifically, the second trimming mechanism 700 has the same structure as the first trimming mechanism 200, and will not be described herein.

In an embodiment, the feeding conveyor belt 800 further includes a feeding conveyor belt 800, the feeding conveyor belt 800 extends in the front-rear direction and is disposed on the machine base 100, and the feeding conveyor belt 800 has a third inlet end and a third outlet end along the conveying direction, and the third outlet end is in butt joint with the first inlet end. The loading conveyor 800 is provided to automatically connect the previous process, and transfers the workpiece from the previous process to the first entrance end of the first workpiece guide groove 110. Specifically, the loading conveyor 800 is a belt conveyor. The feeding conveyor 800 is driven to move by a gear motor. It is envisioned that the loading conveyor 800 may be a chain-mesh conveyor, a drag-type conveyor, or the like.

Specifically, the feeding conveyer 800 is located at the rear of the first workpiece guiding slot 110, and the first barrier 130 relatively far away from the feeding conveyer 800 extends to the front side of the third removal end, so that the workpiece can stop moving at the first entry end.

Specifically, the second barrier 140 relatively far from the first workpiece guiding groove 110 extends to the front side of the first moving-out end, so that the workpiece can stop moving at the workpiece clamping position after sliding along the first workpiece guiding groove 110.

In an embodiment, the grooving mechanism 500 includes a feed driver 510, a feed mount 520, a cutting driver 530, and a grooving saw blade 540, the feed mount 520 is slidably connected to the machine base 100 in a left-right direction, the feed driver 510 is connected to the feed mount 520 and is used for driving the feed mount 520 to move left-right, the cutting driver 530 is disposed on the feed mount 520, the cutting driver 530 is connected to the grooving saw blade 540 and is used for driving the grooving saw blade 540 to rotate, and the grooving saw blade 540 is opposite to the workpiece clamping position left-right. The grooving mechanism 500 is simple and efficient in mechanism and relatively convenient to process.

After the clamping mechanism 400 clamps a fixed workpiece, the cutting driver 530 drives the grooving saw blade 540 to rotate, then the feed driver 510 drives the feed mount 520 to move toward the workpiece, so that the grooving saw blade 540 approaches the workpiece and cuts a mounting groove in the workpiece, then the feed driver 510 drives the feed mount 520 to move away from the workpiece for reset, and then the clamping mechanism 400 can unclamp the workpiece, thereby completing machining of the cutting mounting groove. Specifically, the feed driver 510 includes a gear motor, a screw and a screw nut, the screw nut is mounted on the feed mounting seat 520, the screw is disposed along a left-right direction, and when the gear motor drives the screw to rotate, the feed mounting seat 520 is driven to move left and right by the screw nut. The feeding mount 520 is provided with a guide sleeve, and the machine base 100 is provided with a guide pillar along the left-right direction, and the guide pillar is slidably disposed on the guide bar, so that the feeding mount 520 can slide left-right relative to the machine base 100. The cutting driver 530 is a motor. It may be that the feed driver 510 may also be a structure that outputs linear power, such as a linear motor, a cylinder, etc.; the feeding installation seat 520 may also be provided with a sliding block, the base 100 is provided with a sliding groove, and the sliding block is slidably arranged in the sliding groove, so that the feeding installation seat 520 can move left and right relative to the base 100. The cutting driver 530 may be an internal combustion engine or the like.

It is envisioned that the nicking mechanism 500 may be other configurations, for example, the nicking mechanism 500 includes a multi-axis mechanical arm, a motor and a saw blade, the motor having a rotating shaft coupled to the saw blade, the multi-axis mechanical arm feeding the motor.

In an embodiment, the device further comprises a suction mechanism 900, the suction mechanism 900 is disposed on the stand 100, the suction mechanism 900 includes a protection cover 910 and a connection pipe 920, the protection cover 910 is sleeved on the outer side of the grooving saw blade 540, the protection cover 910 is provided with a ventilation hole, and one end of the connection pipe 920 is connected with the ventilation hole. The shield 910 is provided, and in the process of cutting the magnetic lock body by the grooving saw blade 540, the shield 910 can prevent scraps from splashing, and scraps, dust and harmful gas are sucked through the connecting pipe 920, so that the pollution to the environment during processing is reduced. Specifically, the protection cover 910 is in a runway shape, a part of the protection cover 910 is provided with a yielding port, and the saw blade can cut the magnetic lock body from the yielding port. The other end of the connection pipe 920 is connected to a blower to continuously generate negative pressure in the shield 910, and to suck the harmful gas and the dust in the shield 910.

In an embodiment, the device further comprises a touch screen controller, wherein the touch screen controller is used for controlling the operation of the device, and the control is relatively convenient.

In the embodiment, the clamping mount 410 is provided with a limiting bar 411 extending along the front-rear direction, the limiting bar 411 is located above the second barrier bar 140 with a relatively low height and is spaced from the second barrier bar 140, and a lead arrangement groove 150 is formed between the limiting bar 411 and the second barrier bar 140 with a relatively low height. The lead arranging groove 150 is arranged, so that the leads on the magnetic lock body can be orderly arranged when the magnetic lock body passes through the lead arranging groove 150.

Specifically, a guide surface is provided at the rear end of the limiting bar 411 to facilitate guiding the lead wire into the lead wire arrangement groove 150.

In the description of the present specification, reference to the terms "one embodiment," "some embodiments," "illustrative embodiments," "examples," "specific examples," or "some examples," etc., means that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the utility model. In this specification, schematic representations of the above terms do not necessarily refer to the same embodiments or examples. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

While embodiments of the present utility model have been shown and described, it will be understood by those of ordinary skill in the art that: many changes, modifications, substitutions and variations may be made to the embodiments without departing from the spirit and principles of the utility model, the scope of which is defined by the claims and their equivalents.

Claims (10)

1. A magnetic lock body processing apparatus, comprising:

the machine seat (100) is provided with a first workpiece guide groove (110) along the left-right direction, and the first workpiece guide groove (110) is provided with a first inlet end and a first outlet end;

the first cutting mechanism (200) is arranged on the base (100) and positioned on the side wall of the first workpiece guide groove (110);

a first driving mechanism (300) arranged on the base (100) and used for driving the workpiece to move along the first workpiece guide groove (110);

the clamping mechanism (400) is arranged on the base (100) and used for clamping or loosening a workpiece, and the clamping mechanism (400) is provided with a workpiece clamping position which is in butt joint with the first moving-out end of the first workpiece guide groove (110);

and the grooving mechanism (500) is arranged on the machine base (100) and is used for cutting the mounting groove of the workpiece on the workpiece clamping position.

2. The magnetic lock body processing apparatus according to claim 1, wherein: the first cutting mechanisms (200) are arranged in two, and the two first cutting mechanisms (200) are respectively positioned on two side groove walls of the first workpiece guide groove (110).

3. The magnetic lock body processing apparatus according to claim 1 or 2, wherein: the first trimming mechanism (200) comprises a milling cutter and a trimming driver, the trimming driver is connected with the base (100), the trimming driver is connected with the milling cutter and can drive the milling cutter to rotate, and the milling cutter is located on the side wall of the first workpiece guide groove (110).

4. The magnetic lock body processing apparatus according to claim 1, wherein: the clamping mechanism (400) comprises a clamping mounting seat (410), a first clamping block (420), a second clamping block (430) and a clamping driver (440), wherein the first clamping block (420) is connected to the base (100), the clamping mounting seat (410) is connected to the base (100), the first clamping block (420) and the second clamping block (430) are distributed at intervals front and back, the second clamping block (430) is movably arranged on the clamping mounting seat (410) and the moving direction of the second clamping block (430) is inclined relative to the horizontal direction, the clamping driver (440) is arranged on the clamping mounting seat (410) and used for driving the second clamping block (430) to be close to or far away from the first clamping block (420), a workpiece clamping position is located between the first clamping block (420) and the second clamping block (430), and a workpiece adapting groove (431) is formed in one side of the second clamping block (430) close to the first clamping block (420).

5. The magnetic lock body processing apparatus according to claim 1, wherein: the first driving mechanism (300) comprises a side-moving driver (310), a side-moving mounting seat (320), a lifting driver (330) and a pushing piece (340), wherein the side-moving driver (310) is connected with the side-moving mounting seat (320) and used for driving the side-moving mounting seat (320) to move left and right, the pushing piece (340) is arranged on the side-moving mounting seat (320) in a vertical sliding manner, the lifting driver (330) is arranged on the side-moving mounting seat (320), the lifting driver (330) is connected with the pushing piece (340) and used for driving the pushing piece (340) to move vertically, the pushing piece (340) is located above the first workpiece guide groove (110), and a limiting convex part (341) used for being abutted to the side wall of a workpiece is arranged downwards on the pushing piece (340).

6. The magnetic lock body processing apparatus according to claim 1, wherein: the machine comprises a machine base (100), and is characterized by further comprising a pushing mechanism (600), wherein the pushing mechanism (600) is arranged on the machine base (100), a second workpiece guide groove (120) is formed in the machine base (100) along the front-back direction, the second workpiece guide groove (120) is provided with a second inlet end and a second outlet end, the second inlet end of the second workpiece guide groove (120) is in butt joint with the workpiece clamping position, and the pushing mechanism (600) is used for pushing a workpiece to enter the second workpiece guide groove (120) and move along the second workpiece guide groove (120).

7. The magnetic lock body processing apparatus according to claim 6, wherein: the device further comprises a second trimming mechanism (700), wherein the second trimming mechanism (700) is arranged on the base (100), the groove wall heights of the left side and the right side of the second workpiece guide groove (120) are different, and the second trimming mechanism (700) is positioned on the side wall of the relatively higher side of the second workpiece guide groove (120).

8. The magnetic lock body processing apparatus according to claim 1, wherein: still include material loading conveyer belt (800), material loading conveyer belt (800) along the fore-and-aft direction extend set up in frame (100), material loading conveyer belt (800) have third entering end and third to shift out the end along the direction of delivery, third shift out the end with first entering end butt joint.

9. The magnetic lock body processing apparatus according to claim 1, wherein: the grooving mechanism (500) comprises a feeding driver (510), a feeding mounting seat (520), a cutting driver (530) and a grooving saw blade (540), wherein the feeding mounting seat (520) is connected with the machine base (100) in a sliding mode along the left-right direction, the feeding driver (510) is connected with the feeding mounting seat (520) and used for driving the feeding mounting seat (520) to move left and right, the cutting driver (530) is arranged on the feeding mounting seat (520), the cutting driver (530) is connected with the grooving saw blade (540) and used for driving the grooving saw blade (540) to rotate, and the grooving saw blade (540) is opposite to the left-right workpiece clamping position.

10. The magnetic lock body processing apparatus of claim 9, wherein: still include suction mechanism (900), suction mechanism (900) set up in frame (100), suction mechanism (900) include protection casing (910) and connecting pipe (920), protection casing (910) cover are located the outside of grooving saw bit (540), the air vent has been seted up to protection casing (910), the one end of connecting pipe (920) with the air vent is connected.