CN117445094B - Sensor shell processing perforating device - Google Patents

Abstract

The invention discloses a sensor shell processing perforation device, and belongs to the field of sensor processing. The sensor shell processing perforation device comprises a bottom plate, a top plate, a support rod, a lower template and a lower die holder, wherein the support rod is fixedly connected between the bottom plate and the top plate; the module is internally provided with a through hole, and an annular top block is connected in a sliding manner in the through hole; the upper template is connected to the support rod in a sliding manner, and the bottom of the upper template is fixedly connected with a cover plate; the fixed plate is rotationally connected with a drilling tool; the pressing cylinder is connected to the bottom of the fixed plate in a sliding manner, a round hole corresponding to the drilling tool is formed in the pressing cylinder, and an air outlet nozzle is formed in the inner wall of the pressing cylinder; according to the invention, the sensor shell needing to be perforated can be simultaneously subjected to double-pressure-welding protection, so that the occurrence of cracks or cracks around the sensor shell during perforation can be avoided, the sealing performance of the sensor shell is improved, the aesthetic property is ensured, chips can be simultaneously treated, and the perforation precision is improved.

Description

Sensor shell processing perforating device

Technical Field

The invention relates to the technical field of sensor processing, in particular to a sensor shell processing perforation device.

Background

In the manufacturing process of the sensor, the shell is generally required to be used for installing parts, but in order to facilitate the installation of the parts, the shell is generally required to be perforated.

In the operation of perforating the sensor housing, when the housing material is thin or brittle, the stress is dispersed due to insufficient thickness, so that the stress is concentrated around the perforation, and the occurrence of cracks or fractures is easily caused, and the cracks or fractures weaken the structural strength of the sensor housing and reduce the bearing capacity of the sensor housing; in addition, the sealing performance of the sensor housing is damaged, so that gas or liquid leaks, and the appearance is influenced; and the sweeps generated in the processing process may be accumulated on the perforation aperture, so that the aperture is larger or irregular, and the perforation accuracy is reduced.

Disclosure of Invention

The invention aims to solve the problems in the prior art and provides a sensor shell processing perforation device.

In order to achieve the above purpose, the present invention adopts the following technical scheme:

the utility model provides a sensor housing processing perforating device, includes bottom plate and roof, fixedly connected with bracing piece between bottom plate and the roof still includes:

the lower die plate is fixedly connected to the bottom plate, and a lower die seat is fixedly connected to the lower die plate;

the module is connected to the lower die holder, a shell is placed on the module, a through hole is formed in the module, and an annular ejector block is connected in a sliding manner in the through hole;

the upper template is connected to the supporting rod in a sliding manner, and the bottom of the upper template is fixedly connected with a cover plate;

the fixed plate is arranged in the cover plate and is rotationally connected with a drilling tool;

the pressing cylinder is connected to the bottom of the fixing plate in a sliding mode, a round hole corresponding to the drilling tool is formed in the pressing cylinder, and an air outlet nozzle is arranged on the inner wall of the pressing cylinder.

Preferably, the lower die holder is respectively provided with two long grooves and a sliding groove, the two long grooves are symmetrically arranged on two sides of the sliding groove, the module is connected in the sliding groove in a sliding way, a plurality of slots are arranged between the long grooves and the sliding groove, and the side walls of the shell are respectively inserted into the long grooves and the slots.

Further, the top outer wall fixedly connected with annular cylinder of fixed plate, the annular cylinder sliding connection has annular piston, the bottom fixedly connected with hollow pole of annular piston, the outer wall fixedly connected with connecting plate of pressure section of thick bamboo, the bottom fixedly connected with of hollow pole is on the connecting plate, hollow pole sliding connection is on the fixed plate, the outer wall cover of hollow pole is equipped with the fifth spring, the fifth spring sets up between the bottom of fixed plate and the top outer wall of connecting plate.

Further, the top of hollow pole is equipped with the gas injection hole, the gas injection hole sets up between annular piston and the bottom inner wall of annular cylinder, be equipped with the connecting pipe between the bottom of connecting plate and the pressure section of thick bamboo, the one end and the hollow pole of connecting pipe are linked together, the other end and the mouth of giving vent to anger of connecting pipe are linked together, be equipped with the check valve on the annular piston.

Furthermore, the pressing cylinder and the annular cylinder are respectively provided with a plurality of through holes, the modules are correspondingly provided with a plurality of top openings of the annular cylinders, and the outer wall of the cover plate is provided with air outlet holes.

Still further, the top outer wall of roof is equipped with the cylinder, the cope match-plate pattern sets up the output at the cylinder, fixed link has the motor on the fixed plate, the round tube parcel sets up the outer wall at the motor, the drill bit sets up the output at the motor.

Preferably, the lower die holder is provided with a cavity, the cavity is connected with a pressing block in a sliding manner, the cavity is connected with a rotating rod in a rotating manner, the cavity is connected with a sliding plate in a sliding manner, the pressing block and the sliding plate are respectively arranged above two ends of the rotating rod, the sliding plate is provided with a push rod, the push rod is fixedly connected below the annular push block, and the push rod is arranged above the sliding plate.

Further, a notch is formed in the lower die holder, a notch hole communicated with the cavity is formed in the notch, a bump is fixedly connected to the pressing block and is slidably connected to the notch hole, and a fixing block corresponding to the notch is arranged on the inner wall of the cover plate.

Still further, the inner wall of cavity is first gag lever post and second gag lever post of fixedly connected with respectively, briquetting sliding connection is on first gag lever post, sliding plate sliding connection is on second gag lever post, be equipped with first spring and second spring on first gag lever post and the second gag lever post respectively, first spring sets up between the bottom inner wall of briquetting and cavity, the second spring sets up between the bottom inner wall of sliding plate and cavity.

Still further, be equipped with the axis of rotation in the cavity, the dwang rotates to be connected on the axis of rotation, be equipped with the third spring between the inner wall of annular kicking block and spout, the outer wall at the ejector pin is established to the third spring cover, the bottom of ejector pin is equipped with the fourth spring, the bottom of fourth spring is equipped with the clamp plate, the clamp plate offsets with the top outer wall of sliding plate.

Compared with the prior art, the invention provides a sensor shell processing perforation device, which has the following beneficial effects:

1. this sensor shell processing perforating device, at the in-process that the drill bit descends and realize the perforation, press a section of thick bamboo just to press the peripheral round at the drill bit, thereby can protect the position of drilling, avoid it to produce fracture etc, and the piece etc. that the perforation produced then can get into and press a section of thick bamboo memory, thereby avoid it to pile up on the fenestrate aperture, perforated precision and efficiency have been improved, after the perforation, each part automatic re-setting, can spout gas through the air outlet mouth this moment, thereby will remain the piece in pressing a section of thick bamboo and blow off through the round hole, can be convenient for use next time.

2. This sensor housing processing perforating device, when cover plate downwardly moving, the inside fixed block of cover plate also can synchronous motion, thereby press lug and briquetting downwardly moving, make dwang promote the slide plate and upwards move, thereby the slide plate then can promote the ejector pin and upwards move and drive annular kicking block upwardly moving, the bottom of sensor housing casing is located the one week of perforation position and carries out the crimping protection, make it cooperate with pressing a section of thick bamboo, can realize the dual protection of the bottom and the top of housing casing simultaneously, thereby produce cracked or crack when more efficient avoiding perforating, thereby the structural strength of sensor housing and bearing capacity thereof have been guaranteed.

The device has the advantages that the parts which are not involved in the device are the same as or can be realized by adopting the prior art, the double crimping protection can be simultaneously carried out on the sensor shell needing to be perforated, the occurrence of cracks or cracks around the sensor shell during perforation can be avoided, the sealing performance of the sensor shell is improved, the attractiveness is ensured, chips can be simultaneously treated, and the perforation precision is improved.

Drawings

FIG. 1 is a schematic diagram of a sensor housing processing perforation device according to the present invention;

FIG. 2 is a schematic view of the bottom of a sensor housing processing perforation device according to the present invention;

fig. 3 is a schematic structural diagram of a lower die holder in a sensor housing processing and punching device according to the present invention;

FIG. 4 is a schematic view of a cover plate in a sensor housing processing and perforating device according to the present invention;

FIG. 5 is a cross-sectional view of a cover plate in a sensor housing processing perforation device according to the present invention;

FIG. 6 is a schematic view of the structure of the annular cylinder and the pressure cylinder in the sensor housing processing and perforating device according to the present invention;

FIG. 7 is a schematic cross-sectional view of a lower die holder in a sensor housing processing and punching device according to the present invention;

FIG. 8 is a schematic diagram of a lower die holder in a sensor housing processing and punching device according to the present invention;

FIG. 9 is a schematic cross-sectional side view of a lower die holder in a sensor housing processing and perforating device according to the present invention;

FIG. 10 is a schematic view of the internal structure of a cavity in a sensor housing processing and perforating device according to the present invention;

fig. 11 is an enlarged view of a portion a of fig. 5 of a sensor housing processing perforation device according to the present invention.

In the figure: 1. a bottom plate; 101. a support rod; 102. a top plate; 103. a lower template; 104. a lower die holder; 105. an upper template; 106. a cover plate; 107. a fixed block; 2. a long groove; 201. a slot; 202. a chute; 203. a module; 204. a housing shell; 205. a through hole; 206. a groove is formed; 207. a hole is formed; 3. a bump; 301. briquetting; 302. a first stop lever; 303. a first spring; 304. a rotating lever; 305. a rotating shaft; 306. a sliding plate; 307. a second limit rod; 308. a second spring; 309. a cavity; 4. an annular ejector block; 401. a push rod; 402. a third spring; 403. a fourth spring; 404. a pressing plate; 5. a cylinder; 501. a fixing plate; 502. a motor; 503. a drill; 504. a circular cylinder; 505. an annular piston; 506. a one-way valve; 6. pressing a cylinder; 601. a connecting plate; 602. a hollow rod; 603. an air injection hole; 604. a fifth spring; 605. a connecting pipe; 606. a round hole; 607. and (5) an air outlet nozzle.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments.

In the description of the present invention, it should be understood that the terms "upper," "lower," "front," "rear," "left," "right," "top," "bottom," "inner," "outer," and the like indicate or are based on the orientation or positional relationship shown in the drawings, merely to facilitate description of the present invention and to simplify the description, and do not indicate or imply that the devices or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present invention.

Example 1: referring to fig. 1-11, a sensor housing processing perforation device comprises a bottom plate 1, a top plate 102, a supporting rod 101 fixedly connected between the bottom plate 1 and the top plate 102, a lower die plate 103 fixedly connected to the bottom plate 1, a lower die holder 104 fixedly connected to the lower die plate 103, a module 203 connected to the lower die holder 104, a housing shell 204 placed on the module 203, a through hole 205 arranged in the module 203, an annular top block 4 slidably connected in the through hole 205, an upper die plate 105 slidably connected to the supporting rod 101, a cover plate 106 fixedly connected to the bottom of the upper die plate 105, a fixing plate 501 arranged in the cover plate 106, a drill 503 rotatably connected to the fixing plate 501, a pressing cylinder 6 slidably connected to the bottom of the fixing plate 501, a round hole 606 corresponding to the drill 503 arranged on the pressing cylinder 6, and an air outlet nozzle 607 arranged on the inner wall of the pressing cylinder 6.

In this embodiment, when in use, firstly, the shell 204 of the sensor is placed on the lower die holder 104, when the shell 204 of the sensor is perforated, the upper die plate 105 is controlled to descend, thereby driving the cover plate 106 to descend, the pressure cylinder 6 in the cover plate 106 can press the shell 204, the shell 204 can be perforated by the rotary drill 503, and the pressure cylinder 6 is just pressed around the drill 503, so that the position of the drill can be protected, cracks and the like are avoided, meanwhile, when the cover plate 106 descends to drive the drill 503 to perform perforation operation, the annular top block 4 in the module 203 is lifted, thereby propping against the bottom of the shell 204, and is matched with the pressure cylinder 6, the drill position of the shell 204 can be protected, and the pressure cylinder 6 can also be positioned preliminarily after the pressure cylinder 204 is pressed, and simultaneously can move upwards at the bottom of the fixed plate 501, so that the shell 204 can be perforated better, and the produced chips and the like can enter the pressure cylinder 503 to automatically store the pressure cylinder 607, so that the hole diameter of the pressure cylinder can be prevented from being stacked in the hole, and the hole can be discharged by the air tap 6, and the hole can be discharged after the hole is completely, and the hole is completely blown out by the hole 6.

Example 2: referring to fig. 1-7 and 11, a sensor housing processing perforation device comprises a bottom plate 1 and a top plate 102, wherein a supporting rod 101 is fixedly connected between the bottom plate 1 and the top plate 102, the sensor housing processing perforation device further comprises a lower die plate 103 fixedly connected to the bottom plate 1, a lower die holder 104 is fixedly connected to the lower die plate 103, a module 203 is connected to the lower die holder 104, a housing shell 204 is placed on the module 203, a through hole 205 is formed in the module 203, an annular top block 4 is slidably connected to the through hole 205, the sensor housing processing perforation device further comprises an upper die plate 105 slidably connected to the supporting rod 101, a cover plate 106 is fixedly connected to the bottom of the upper die plate 105, a fixing plate 501 is arranged in the cover plate 106, a drill 503 is rotatably connected to the fixing plate 501, a pressing cylinder 6 is slidably connected to the bottom of the fixing plate 501, a round hole 606 corresponding to the drill 503 is formed in the pressing cylinder 6, and an air outlet nozzle 607 is formed in the inner wall of the pressing cylinder 6.

The lower die holder 104 is respectively provided with a long groove 2 and a sliding groove 202, the number of the long grooves 2 is two, the two long grooves 2 are symmetrically arranged on two sides of the sliding groove 202, the module 203 is slidably connected in the sliding groove 202, a plurality of slots 201 are arranged between the long grooves 2 and the sliding groove 202, and the side walls of the shell 204 are respectively inserted into the long grooves 2 and the slots 201.

The top outer wall fixedly connected with ring section of thick bamboo 504 of fixed plate 501, ring section of thick bamboo 504 sliding connection has annular piston 505, and the bottom fixedly connected with hollow pole 602 of annular piston 505 presses the outer wall fixedly connected with connecting plate 601 of section of thick bamboo 6, and the bottom fixedly connected with of hollow pole 602 is on connecting plate 601, and hollow pole 602 sliding connection is on fixed plate 501, and the outer wall cover of hollow pole 602 is equipped with fifth spring 604, and fifth spring 604 sets up between the bottom of fixed plate 501 and the top outer wall of connecting plate 601.

The top of hollow rod 602 is equipped with gas injection hole 603, and gas injection hole 603 sets up between annular piston 505 and the bottom inner wall of annular cylinder 504, is equipped with connecting pipe 605 between the bottom of connecting plate 601 and the pressure section of thick bamboo 6, and one end of connecting pipe 605 is linked together with hollow rod 602, and the other end of connecting pipe 605 is linked together with air outlet nozzle 607, is equipped with check valve 506 on the annular piston 505.

The pressure cylinder 6 and the annular cylinder 504 are respectively provided with a plurality of through holes 205, the corresponding modules 203 are provided with a plurality of through holes 205, the top of the annular cylinder 504 is opened, and the outer wall of the cover plate 106 is provided with air outlet holes.

The top outer wall of roof 102 is equipped with cylinder 5, and cope match-plate pattern 105 sets up the output at cylinder 5, and fixed plate 501 is last to be linked with motor 502, and the parcel of a ring section of thick bamboo 504 sets up the outer wall at motor 502, and drill bit 503 sets up the output at motor 502.

In this embodiment, firstly, the shell 204 of the sensor is placed on the lower die holder 104, when the shell 204 of the sensor is perforated, the upper die plate 105 at the output end of the sensor is controlled to descend by the air cylinder 5, so as to drive the cover plate 106 to descend, the pressing cylinder 6 in the cover plate 106 presses the shell 204, meanwhile, the motor 502 is started, so as to drive the drill 503 at the output end to start rotating, the shell 204 can be perforated by the drill 503, after the pressing cylinder 6 is pressed on the shell 204, the cover plate 106 drives the fixing plate 501 to move downwards, so that the pressing cylinder 6 slides, on one hand, the pressing cylinder 6 can be fixed on the shell 204, on the other hand, the pressing cylinder 6 can be pressed for one circle of the drill 503, so that cracks and the like around the drill 503 are avoided when the drill 503 is perforated, the perforated position can be effectively protected, then the drill 503 extends out through the round hole 606 to punch the shell 204 of the sensor, meanwhile, the chips and the like generated by punching are screwed into the pressing cylinder 6 through the upper part of the drill 503, so that the impact of the chips and the like on the punched hole diameter on the punching is avoided, the pressing cylinder 6 drives the hollow rod 602 on the connecting plate 601 to slide on the fixed plate 501 when sliding, so that the annular piston 505 in the annular cylinder 504 is pushed to want to move, when the annular piston 505 moves upwards, the air is pumped through the one-way valve 506, so that the air is injected between the annular piston 505 and the bottom inner wall of the annular cylinder 504, meanwhile, the fifth spring 604 is compressed, the upper die plate 105 at the output end is driven to move upwards through the air cylinder 5 after the punching operation is finished, so that the cover plate 106 is driven to move upwards, and then the pressing cylinder 6 is reset again under the action of the fifth spring 604, and meanwhile, the annular piston 505 is reset, and gas between the annular piston 505 and the inner wall of the bottom of the annular cylinder 504 is discharged, so that the gas enters the hollow rod 602 through the gas injection hole 603, then enters the connecting pipe 605 and is discharged through the gas outlet nozzle 607, and therefore, the chips and the like remained in the pressure cylinder 6 are blown off through the round hole 606, and the repeated use is facilitated.

It should be noted that, the check valve 506 is disposed on the annular piston 505, gas can enter between the annular piston 505 and the bottom inner wall of the annular cylinder 504 through the check valve 506, and can not be discharged between the annular piston 505 and the bottom inner wall of the annular cylinder 504 through the check valve 506, when the annular piston 505 rises, gas can be sucked through the check valve 506, and when the annular piston 505 descends, gas can only enter the hollow rod 602 through the gas injection hole 603, so as to be conveniently discharged through the gas outlet nozzle 607, and the chips are blown off, and the top opening of the annular cylinder 504 is also provided with the gas outlet holes on both side walls of the cover plate 106, so that gas can conveniently enter between the fixing plate 501 and the top inner wall of the cover plate 106, thereby facilitating gas suction.

And a plurality of slots 201 are arranged between the long slot 2 and the sliding groove 202, so that the sensor shell 204 with different sizes can be respectively inserted into the slots 201 at different positions, the use range is enlarged, and the shell 204 can be conveniently taken down through the long slot 2 and the sliding groove 202 after perforation is finished.

Example 3: referring to fig. 1-4 and fig. 7-10, a sensor shell processing perforation device comprises a bottom plate 1 and a top plate 102, wherein a supporting rod 101 is fixedly connected between the bottom plate 1 and the top plate 102, the sensor shell processing perforation device further comprises a lower template 103 fixedly connected to the bottom plate 1, a lower die holder 104 is fixedly connected to the lower template 103, a module 203 is connected to the lower die holder 104, a shell 204 is placed on the module 203, a through hole 205 is formed in the module 203, an annular top block 4 is slidably connected to the through hole 205, the sensor shell processing perforation device further comprises an upper template 105 slidably connected to the supporting rod 101, a cover plate 106 is fixedly connected to the bottom of the upper template 105, a fixing plate 501 is arranged in the cover plate 106, a drill bit 503 is rotatably connected to the fixing plate 501, a pressing cylinder 6 is slidably connected to the bottom of the fixing plate 501, a round hole 606 corresponding to the drill bit 503 is formed in the pressing cylinder 6, and an air outlet nozzle 607 is formed in the inner wall of the pressing cylinder 6.

The lower die holder 104 is provided with a cavity 309, a pressing block 301 is connected in the cavity 309 in a sliding way, a rotating rod 304 is connected in the cavity 309 in a rotating way, a sliding plate 306 is connected in the cavity 309 in a sliding way, the pressing block 301 and the sliding plate 306 are respectively arranged above two ends of the rotating rod 304, a push rod 401 is arranged on the sliding plate 306, the push rod 401 is fixedly connected below the annular push block 4, and the push rod 401 is arranged above the sliding plate 306.

The lower die holder 104 is provided with a notch 206, a notch 207 communicated with the cavity 309 is arranged in the notch 206, the pressing block 301 is fixedly connected with a convex block 3, the convex block 3 is slidably connected in the notch 207, and the inner wall of the cover plate 106 is provided with a fixed block 107 corresponding to the notch 206.

The inner wall of cavity 309 is fixedly connected with first gag lever post 302 and second gag lever post 307 respectively, briquetting 301 sliding connection is on first gag lever post 302, and slide plate 306 sliding connection is on second gag lever post 307, is equipped with first spring 303 and second spring 308 on first gag lever post 302 and the second gag lever post 307 respectively, and first spring 303 sets up between briquetting 301 and the bottom inner wall of cavity 309, and second spring 308 sets up between slide plate 306 and the bottom inner wall of cavity 309.

A rotating shaft 305 is arranged in the cavity 309, the rotating rod 304 is rotatably connected to the rotating shaft 305, a third spring 402 is arranged between the annular ejector block 4 and the inner wall of the chute 202, the third spring 402 is sleeved on the outer wall of the ejector rod 401, a fourth spring 403 is arranged at the bottom of the ejector rod 401, a pressing plate 404 is arranged at the bottom of the fourth spring 403, and the pressing plate 404 abuts against the top outer wall of the sliding plate 306.

In this embodiment, during perforation, the cover plate 106 is first controlled to move downward, then the top of the casing shell 204 can be fixed by the pressing cylinder 6, and meanwhile, the top of the casing shell 204 can be pressed and protected at a position around the drill bit 503 by the pressing cylinder 6, so as to avoid cracking and the like during perforation, and when the cover plate 106 moves downward, the fixing block 107 inside the cover plate 106 also moves synchronously, so that the bump 3 in the notch 206 is pressed and moved, then the bump 3 slides in the notch 207, and meanwhile, the pressing block 301 is driven to move downward, when the pressing block 301 moves downward, one end of the rotating rod 304 is pushed to move downward, so that the rotating rod 304 rotates around the rotating shaft 305, therefore, one end of the rotating rod 304 far away from the pressing block 301 moves upward, so as to push the sliding plate 306 moves upward, and the sliding plate 306 pushes the ejector rod 401 to move upward, so as to drive the annular ejector block 4 to move upward, and the bottom of the casing shell 204 is positioned at the perforation position, so that the fixing block 107 is matched with the pressing cylinder 6, so that the bottom and the top of the casing shell 204 can be protected at the same time, and the bottom and the top of the casing 204 can be protected, and the cracking and the crack of the casing can be avoided.

In this application, when slide plate 306 upwards moves, can promote clamp plate 404 first, then promote ejector pin 401 through fourth spring 403 and rise, and then promote annular kicking block 4 and rise to make its bottom with shell casing 204 contact, form the crimping protection, and through the setting of fourth spring 403, can cushion annular kicking block 4, avoid because the power that dwang 304 stirred great leads to annular kicking block 4 to jack up shell casing 204, influence the use.

The first limiting rod 302 and the second limiting rod 307 which limit the pressing block 301 and the sliding plate 306 are further arranged in the cavity 309, so that the pressing block 301 and the sliding plate 306 are more stable when moving, the first spring 303 is compressed when the pressing block 301 moves downwards, the second spring 308 is stretched when the sliding plate 306 moves upwards, the third spring 402 is stretched when the annular jacking block 4 rises, after perforation is completed, the compressed first spring 303, the stretched second spring 308 and the third spring 402 are automatically reset after the cover plate 106 moves upwards to reset, the pressing block 301, the sliding plate 306 and the annular jacking block 4 are automatically reset, repeated use is facilitated, the annular jacking block 4 is reset, and the purpose that the annular jacking block 4 is not in contact with the bottom of the shell 204 is achieved.

The foregoing is only a preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art, who is within the scope of the present invention, should make equivalent substitutions or modifications according to the technical scheme of the present invention and the inventive concept thereof, and should be covered by the scope of the present invention.

Claims (3)

1. The utility model provides a sensor housing processing perforating device, includes bottom plate (1) and roof (102), fixedly connected with bracing piece (101) between bottom plate (1) and roof (102), its characterized in that still includes:

the lower die plate (103) is fixedly connected to the bottom plate (1), and a lower die base (104) is fixedly connected to the lower die plate (103);

the module (203) is connected to the lower die holder (104), a shell (204) is placed on the module (203), a through hole (205) is formed in the module (203), and an annular top block (4) is connected in a sliding manner in the through hole (205);

the upper die plate (105) is connected to the supporting rod (101) in a sliding manner, and a cover plate (106) is fixedly connected to the bottom of the upper die plate (105);

the fixed plate (501) is arranged in the cover plate (106), and the fixed plate (501) is rotationally connected with a drill (503);

the pressing cylinder (6) is connected to the bottom of the fixed plate (501) in a sliding manner, a round hole (606) corresponding to the drilling tool (503) is formed in the pressing cylinder (6), and an air outlet nozzle (607) is formed in the inner wall of the pressing cylinder (6);

the top outer wall of the fixed plate (501) is fixedly connected with a circular cylinder (504), the circular cylinder (504) is internally and slidably connected with an annular piston (505), the bottom of the annular piston (505) is fixedly connected with a hollow rod (602), the outer wall of the pressing cylinder (6) is fixedly connected with a connecting plate (601), the bottom of the hollow rod (602) is fixedly connected with the connecting plate (601), the hollow rod (602) is slidingly connected with the fixed plate (501), a fifth spring (604) is sleeved on the outer wall of the hollow rod (602), and the fifth spring (604) is arranged between the bottom of the fixed plate (501) and the top outer wall of the connecting plate (601);

the top of the hollow rod (602) is provided with an air injection hole (603), the air injection hole (603) is arranged between the annular piston (505) and the bottom inner wall of the annular cylinder (504), a connecting pipe (605) is arranged between the bottom of the connecting plate (601) and the pressure cylinder (6), one end of the connecting pipe (605) is communicated with the hollow rod (602), the other end of the connecting pipe (605) is communicated with an air outlet nozzle (607), and the annular piston (505) is provided with a one-way valve (506);

the pressure cylinder (6) and the annular cylinder (504) are provided with a plurality of through holes (205) correspondingly arranged on the module (203), the top of the annular cylinder (504) is provided with an opening, and the outer wall of the cover plate (106) is provided with an air outlet;

the die comprises a lower die holder (104), wherein a cavity (309) is formed in the lower die holder (104), a pressing block (301) is connected in a sliding mode in the cavity (309), a rotating rod (304) is connected in a rotating mode in the cavity (309), a sliding plate (306) is connected in a sliding mode in the cavity (309), the pressing block (301) and the sliding plate (306) are respectively arranged above two ends of the rotating rod (304), a push rod (401) is arranged on the sliding plate (306), and the push rod (401) is fixedly connected below an annular push block (4) and is arranged above the sliding plate (306);

a notch (206) is formed in the lower die holder (104), a notch hole (207) communicated with the cavity (309) is formed in the notch (206), a bump (3) is fixedly connected to the pressing block (301), the bump (3) is slidably connected in the notch hole (207), and a fixed block (107) corresponding to the notch (206) is arranged on the inner wall of the cover plate (106);

the inner wall of the cavity (309) is fixedly connected with a first limit rod (302) and a second limit rod (307) respectively, the pressing block (301) is connected to the first limit rod (302) in a sliding mode, the sliding plate (306) is connected to the second limit rod (307) in a sliding mode, the first limit rod (302) and the second limit rod (307) are sleeved with a first spring (303) and a second spring (308) respectively, the first spring (303) is arranged between the pressing block (301) and the bottom inner wall of the cavity (309), and the second spring (308) is arranged between the sliding plate (306) and the bottom inner wall of the cavity (309);

be equipped with axis of rotation (305) in cavity (309), dwang (304) rotate and connect on axis of rotation (305), be equipped with third spring (402) between the inner wall of annular kicking block (4) and spout (202), outer wall at ejector pin (401) is established to third spring (402) cover, the bottom of ejector pin (401) is equipped with fourth spring (403), the bottom of fourth spring (403) is equipped with clamp plate (404), clamp plate (404) offset with the top outer wall of sliding plate (306).

2. The sensor housing processing perforation device according to claim 1, wherein the lower die holder (104) is respectively provided with a long groove (2) and a sliding groove (202), the long grooves (2) are two, the two long grooves (2) are symmetrically arranged on two sides of the sliding groove (202), the module (203) is slidably connected in the sliding groove (202), a plurality of slots (201) are arranged between the long grooves (2) and the sliding groove (202), and the side walls of the housing shell (204) are respectively inserted into the long grooves (2) and the slots (201).

3. The sensor housing processing perforation device according to claim 1, wherein an air cylinder (5) is arranged on the top outer wall of the top plate (102), the upper die plate (105) is arranged at the output end of the air cylinder (5), a motor (502) is fixedly connected to the fixing plate (501), the annular cylinder (504) is wrapped on the outer wall of the motor (502), and the drill bit (503) is arranged at the output end of the motor (502).