CN221158831U - Chamfer processing device for temperature sensor - Google Patents

Abstract

The utility model relates to the technical field of chamfering processing of temperature sensors, in particular to a chamfering processing device of a temperature sensor, which is characterized in that materials are automatically arranged through a feeding device and conveyed into a fixing device one by one, a sensor probe rod is limited and fixed through the fixing device, the sensor probe rod is subjected to chamfering processing through the chamfering device, metal scraps generated by processing are collected through a collecting device, and the sensor probe rod subjected to processing is collected through a storing device; the auxiliary device is convenient for operators to control and observe the production condition of the equipment, so that the practicability of the device is improved; including loading attachment, fixing device, chamfer device, collection device, storage device and auxiliary device, fixing device installs on loading attachment, and chamfer device installs on loading attachment, and collection device installs on chamfer device, and storage device installs in loading attachment, and auxiliary device installs on loading attachment.

Description

Chamfer processing device for temperature sensor

Technical Field

The utility model relates to the technical field of chamfering processing of temperature sensors, in particular to a chamfering processing device of a temperature sensor.

Background

The condition that temperature sensor needs to carry out chamfer processing mainly depends on specific application scene and sensor's design, generally speaking, if there is obvious acute angle or edge in the mounted position of sensor, just need carry out chamfer processing to avoid sensor damage or measuring error, chamfer processing can also improve the installation accuracy and the stability of sensor simultaneously, guarantees measuring accuracy, so when aiming at different application scenes, can carry out chamfer processing to temperature sensor probe rod part before the product leaves the factory.

The utility model patent in China with the application number of CN202222858992.4 in the prior art relates to a sensor chamfering mechanism which comprises a workbench, a U-shaped frame, an adjusting component and a stabilizing component, and can ensure the stability of a chamfering tool in the high-speed rotation process.

However, the above device has the following problems in practical use: firstly, the device does not have automatic feeding capability, so that a large amount of labor force is consumed in a large-batch processing process, and the degree of automation is insufficient; secondly, the fixing process of the device depends on manual operation, so that the production efficiency of the equipment is low and the consumed time is long.

Disclosure of utility model

In order to solve the technical problems, the utility model provides a sensor probe rod which is automatically arranged through a feeding device and conveyed into a fixing device one by one, wherein the sensor probe rod is limited and fixed through the fixing device, the sensor probe rod is subjected to chamfering processing through a chamfering device, metal scraps generated by processing are collected through a collecting device, and the sensor probe rod which is subjected to processing is collected through a storage device; the temperature sensor chamfering processing device is convenient for operators to control and observe the equipment production condition through the auxiliary device, and the practicability of the device is improved.

The utility model relates to a temperature sensor chamfering device which comprises a feeding device, a fixing device, a chamfering device, a collecting device, a storage device and an auxiliary device, wherein the fixing device is arranged on the feeding device; the sensor probe rod is limited and fixed through the fixing device, chamfering is carried out on the sensor probe rod through the chamfering device, metal scraps generated by processing are collected through the collecting device, and the sensor probe rod after processing is collected through the storing device; the auxiliary device is convenient for operators to control and observe the equipment production condition, and the practicability of the device is improved.

Preferably, the feeding device comprises a vibrating disc, a processing box, a top plate, a portal frame, a first speed reducing motor and a poking soft board, wherein the right end face of the vibrating disc is connected with the processing box, the top plate is installed at the upper part in the processing box, a feeding groove is formed in the upper left part of the upper end face of the top plate, a discharging hole is formed in the right part of the upper end face of the top plate, the feeding groove extends rightwards to be connected with the discharging hole, the output end of the vibrating disc is connected with the left part of the upper end face of the top plate, the portal frame is installed at the right part of the upper end face of the processing box, the first speed reducing motor is installed at the rear part of the upper end face of the portal frame, the output end of the first speed reducing motor penetrates through the lower end face of the portal frame to extend to the lower side of the portal frame, and a plurality of groups of poking soft boards are installed at the output end of the first speed reducing motor; the sensor probe rods inside the vibration disc are sent into the feeding grooves on the upper end face of the top plate one by one to be arranged and move rightwards along with vibration, the probe rods in the feeding grooves are intercepted by stirring the soft plate, the first gear motor is started to transmit power to the stirring soft plate to drive the stirring soft plate to rotate, so that the probe rods in the feeding grooves are sent into the discharging holes one by one to fall down, and all the probe rods are in the same vertical state through the cooperation of the vibration disc and the feeding grooves on the top plate.

Preferably, the fixing device comprises a receiving hopper, first electric cylinders, clamping jaws, a rotating shaft, a baffle and a second gear motor, wherein the front end surface and the rear end surface of the receiving hopper are respectively connected with the front end surface and the rear end surface in the processing box, the receiving hopper is positioned at the lower side of a discharge hole on the top plate, a group of first electric cylinders are respectively arranged on the left side and the right side of the lower part of the receiving hopper, the moving ends of the first electric cylinders respectively penetrate through the side surfaces of the receiving hopper and enter the receiving hopper to be connected with the clamping jaws, the front end surface and the rear end surface of the rotating shaft are respectively connected with the front end surface and the rear end surface in the processing box, the baffle is connected on the side surface of the rotating shaft, the rotating shaft is positioned at the lower side of the receiving hopper, the second gear motor is arranged on the front end surface of the processing box, and the output end of the second gear motor penetrates through the front end surface of the processing box and is connected with the rotating shaft; opening the second gear motor and driving the rotating shaft to rotate by the power transmission to the rotating shaft so that the baffle is in a horizontal state and is positioned at the lower side of the receiving hopper, enabling the probe rod with the falling discharge opening to enter the receiving hopper, supporting the lower part of the probe rod by the upper end face of the baffle, and then opening two groups of first electric cylinders so that the two groups of clamping jaws fix the position of the probe rod, so that subsequent chamfering processing is facilitated.

Preferably, the chamfering device comprises a second electric cylinder, a lifting box, a motor and a cutter head, wherein the second electric cylinder is arranged at the right part of the inner end surface of the processing box, the lifting box is connected to the moving end of the second electric cylinder, the motor is arranged on the upper end surface in the lifting box, and the output end of the motor penetrates through the upper end surface of the lifting box to extend to the upper side of the lifting box and is connected with the cutter head; after fixing the position of the probe rod by the fixing device, controlling the baffle to rotate to the lower side of the rotating shaft, controlling the second electric cylinder to extend to enable the tool bit to move upwards to be in contact with the probe rod, starting the motor to transmit power to the tool bit to drive the tool bit to rotate to chamfer the bottom of the probe rod, and improving the automation degree of the device.

Preferably, the collecting device comprises a collecting box, a vibrating motor and a storage bin, wherein a chamfer is arranged at the edge of the upper end face of the lifting box, the collecting box is arranged at the upper part of the side face of the lifting box, the vibrating motor is arranged on the side face of the collecting box, the storage bin is arranged at the right part of the lower end face of the processing box, and the input end of the storage bin is communicated with the inner bottom of the collecting box through a hose; the metal scraps produced during chamfering processing of the cutter head slide into the collecting box along with the radian on the upper end face of the lifting box, then the vibrating motor is started to transmit power to the collecting box to drive the collecting box to vibrate, so that the metal scraps in the collecting box are uniformly distributed, the metal scraps located at the connecting part of the hose slide into the storage bin along with the hose to be stored, and the influence of the scraps on the internal environment of equipment is reduced.

Preferably, the material storage device comprises a collection frame and a support rod, the end face of the inner bottom of the processing box is connected with the collection frame through the support rod, the right part of the collection frame is upward lifted, a material storage slot is arranged in the middle of the collection frame, chamfers are arranged on the left and right sides of the upper end face of the material storage slot, and the right part of the collection frame is positioned on the left lower side of the baffle plate in a horizontal state; after the machining is finished, the second electric cylinders are controlled to shrink, the baffle is simultaneously enabled to rotate to be positioned at the lower side of the receiving hopper in a horizontal state, then, the two groups of first electric cylinders are controlled to shrink, the lower part of the probe rod is supported by the upper end face of the baffle, then, the baffle is controlled to slowly rotate, the probe rod on the baffle slowly slides onto the upper end face of the right part of the collecting frame, and the lower part of the probe rod slides into the storage slot and slides to the left part of the collecting frame along with the storage slot through the chamfer of the storage slot.

Preferably, the auxiliary device comprises a PLC controller, an observation window and a sealing door, wherein the PLC controller is arranged on the front end face of the processing box, the observation window is arranged on the right part of the front end face of the processing box, and the sealing door is arranged on the lower part of the front end face of the processing box; all electric appliance switches of the equipment are integrated controlled through the PLC, operators observe the chamfering condition inside the equipment through the observation window, the operators take out materials on the material storage device through the sealing door, the equipment is convenient to overhaul, and the practicability of the device is improved

Compared with the prior art, the utility model has the beneficial effects that: the sensor probe rod is limited and fixed through the fixing device, chamfering is carried out on the sensor probe rod through the chamfering device, metal scraps generated by processing are collected through the collecting device, and the sensor probe rod after processing is collected through the storing device; the auxiliary device is convenient for operators to control and observe the equipment production condition, and the practicability of the device is improved.

Drawings

FIG. 1 is a schematic cross-sectional view of the present utility model;

FIG. 2 is a schematic elevational view of the present utility model;

FIG. 3 is a schematic top view of the present utility model;

FIG. 4 is a schematic diagram of an isometric structure of a storage device;

The reference numerals in the drawings: 1. a vibration plate; 2. a processing box; 3. a top plate; 4. a door frame; 5. a first gear motor; 6. stirring the soft board; 7. a receiving hopper; 8. a first electric cylinder; 9. a clamping jaw; 10. a rotating shaft; 11. a baffle; 12. a second gear motor; 13. a second electric cylinder; 14. a lifting box; 15. a motor; 16. a cutter head; 17. a collection box; 18. a vibration motor; 19. a storage bin; 20. a collection rack; 21. a support rod; 22. a PLC controller; 23. an observation window; 24. sealing the door.

Description of the embodiments

In order that the utility model may be readily understood, a more complete description of the utility model will be rendered by reference to the appended drawings. This utility model may be embodied in many different forms and is not limited to the embodiments described herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete.

Examples

The fixing device, the chamfering device, the storage device and the auxiliary device shown in figures 1, 2, 3 and 4 are all arranged on the feeding device;

Firstly, starting a vibration disc 1 to send sensor probe rods in the vibration disc 1 into a feed groove on the upper end face of a top plate 3 one by one, arranging and moving rightwards along with vibration, intercepting the probe rods in the feed groove by stirring a soft plate 6, starting a first speed reducing motor 5 to transmit power to the stirring soft plate 6 to drive the stirring soft plate 6 to rotate, so that the probe rods in the feed groove are gradually stirred into a discharge hole to fall, the probe rods falling from the discharge hole enter the inside of a receiving hopper 7, the upper end face of a baffle plate 11 supports the lower part of the probe rods, then starting two groups of first electric cylinders 8 to fix the positions of the probe rods by two groups of clamping jaws 9, controlling the baffle plate 11 to rotate to the lower side of a rotating shaft 10, controlling a second electric cylinder 13 to stretch to enable a cutter head 16 to be in contact with the probe rods, starting a motor 15 to drive the cutter head 16 to rotate to chamfer the bottom of the probe rods, controlling the second electric cylinder 13 to shrink after finishing processing, simultaneously enabling the baffle plate 11 to rotate to be positioned at the lower side of the receiving hopper 7, then controlling two groups of first electric cylinders 8 to shrink so that the lower end faces of the probe rods are supported by the upper end faces of the baffle plate 11, and slowly sliding down to the baffle plate 20, namely, the baffle plate 20 can slowly slide down to the upper end face of the baffle plate 20 to the upper end face of the baffle plate;

The feeding device comprises a vibration disc 1, a processing box 2, a top plate 3, a door frame 4, a first speed reducing motor 5 and a poking soft plate 6, wherein the right end face of the vibration disc 1 is connected with the processing box 2, the top plate 3 is arranged at the upper part in the processing box 2, a feeding groove is formed in the upper left part of the upper end face of the top plate 3, a discharging hole is formed in the right part of the upper end face of the top plate 3, the feeding groove extends rightward and is connected with the discharging hole, the output end of the vibration disc 1 is connected with the left part of the upper end face of the top plate 3, the door frame 4 is arranged at the right part of the upper end face of the processing box 2, the first speed reducing motor 5 is arranged at the rear part of the upper end face of the door frame 4, the output end of the first speed reducing motor 5 penetrates through the lower end face of the door frame 4 to the lower side of the door frame 4, and a plurality of groups of poking soft plates 6 are arranged at the output end of the first speed reducing motor 5;

The fixing device comprises a receiving hopper 7, a first electric cylinder 8, clamping claws 9, a rotating shaft 10, a baffle 11 and a second gear motor 12, wherein the front end surface and the rear end surface of the receiving hopper 7 are respectively connected with the front end surface and the rear end surface in the processing box 2, the receiving hopper 7 is positioned at the lower side of a discharge hole on the top plate 3, a group of first electric cylinders 8 are respectively arranged at the left side and the right side of the lower part of the receiving hopper 7, the moving ends of the first electric cylinders 8 respectively penetrate through the side surfaces of the receiving hopper 7 and enter the receiving hopper 7 to be connected with the clamping claws 9, the front end surface and the rear end surface of the rotating shaft 10 are respectively connected with the front end surface and the rear end surface in the processing box 2, the baffle 11 is connected on the side surface of the rotating shaft 10, the rotating shaft 10 is positioned at the lower side of the receiving hopper 7, the second gear motor 12 is arranged on the front end surface of the processing box 2, and the output end of the second gear motor 12 penetrates through the front end surface of the processing box 2 to be connected with the rotating shaft 10;

The chamfering device comprises a second electric cylinder 13, a lifting box 14, a motor 15 and a cutter head 16, wherein the second electric cylinder 13 is arranged at the right part of the inner end surface of the processing box 2, the lifting box 14 is connected to the moving end of the second electric cylinder 13, the motor 15 is arranged on the upper end surface in the lifting box 14, and the output end of the motor 15 passes through the upper end surface of the lifting box 14 and extends to the upper side of the lifting box 14 to be connected with the cutter head 16;

The material storage device comprises a collection frame 20 and a support rod 21, wherein the collection frame 20 is connected to the inner bottom end surface of the processing box 2 through the support rod 21, the right part of the collection frame 20 is upward lifted, a material storage slot is formed in the middle of the collection frame 20, chamfers are formed on the left and right sides of the upper end surface of the material storage slot, and the right part of the collection frame 20 is positioned on the left lower side of the baffle 11 in a horizontal state;

All the electrical appliance switches of the equipment are integrally controlled through the PLC 22, an operator can observe the chamfering condition inside the equipment conveniently through the observation window 23, the operator can take out materials on the material storage device conveniently through the sealing door 24, the equipment is convenient to overhaul internally, and the practicability of the device is improved;

The sensor probe rods are automatically arranged through the feeding device and conveyed into the fixing device one by one, are limited and fixed through the fixing device, are subjected to chamfering through the chamfering device, and are collected through the storage device; the auxiliary device is convenient for operators to control and observe the equipment production condition, and the practicability of the device is improved.

Examples

The improvement on the first embodiment comprises a collecting device which is arranged on the chamfering device in a collecting way;

collecting metal scraps generated by processing through a collecting device;

The metal scraps generated during chamfering of the cutter head 16 slide into the collecting box 17 along with the radian on the upper end face of the lifting box 14, then the vibrating motor 18 is started to transmit power to the collecting box 17 to drive the collecting box 17 to vibrate, so that the metal scraps in the collecting box 17 are uniformly distributed, the metal scraps positioned at the connecting part of the hose slide into the storage bin 19 along with the hose for storage, and the influence of the scraps on the internal environment of equipment is reduced;

The collecting device comprises a collecting box 17, a vibrating motor 18 and a storage bin 19, wherein a chamfer is arranged on the edge of the upper end face of the lifting box 14, the collecting box 17 is arranged on the upper portion of the side face of the lifting box 14, the vibrating motor 18 is arranged on the side face of the collecting box 17, the storage bin 19 is arranged on the right portion of the lower end face of the processing box 2, and the input end of the storage bin 19 is communicated with the inner bottom of the collecting box 17 through a hose.

As shown in fig. 1 to 4, in the temperature sensor chamfering device of the present utility model, when in operation, firstly, the vibration plate 1 is started to feed sensor probe rods inside the vibration plate 1 into the feed chute on the upper end face of the top plate 3 one by one, and the sensor probe rods are arranged and move rightwards along with the vibration, the probe rods in the feed chute are intercepted by stirring the soft plate 6, the first gear motor 5 is started to transmit power to the stirring soft plate 6 to drive the stirring soft plate 6 to rotate, so that the probe rods in the feed chute are conveyed to the discharge hole one by one and fall down, the probe rods with falling discharge holes enter the receiving hopper 7, then the upper end face of the baffle plate 11 supports the lower part of the probe rods, then two groups of first electric cylinders 8 are started to fix the positions of the probe rods by two groups of clamping jaws 9, then the baffle plate 11 is controlled to rotate to the lower side of the rotating shaft 10, then the second electric cylinders 13 are controlled to stretch to enable the cutter head 16 to move upwards to contact with the probe rods, then, starting a motor 15 to transmit power to a cutter head 16 to drive the cutter head 16 to rotate so as to chamfer the bottom of the probe rod, then sliding metal scraps generated during chamfering the cutter head 16 into a collecting box 17 along with the radian on the upper end face of a lifting box 14, then starting a vibrating motor 18 to transmit power to the collecting box 17 to drive the collecting box 17 to vibrate, so that the metal scraps in the collecting box 17 are uniformly distributed, the metal scraps positioned at the connecting part of a hose slide into a storage bin 19 along with the hose to be stored, controlling a second electric cylinder 13 to shrink after finishing the machining, simultaneously enabling a baffle 11 to rotate to a horizontal state and be positioned at the lower side of a receiving hopper 7, controlling two groups of first electric cylinders 8 to shrink so that the lower part of the probe rod is supported by the upper end face of the baffle 11, then controlling the baffle 11 to slowly rotate so that the probe rod on the baffle 11 slowly slides onto the upper end face of the right part of a collecting frame 20, by chamfering the storage slot, the lower part of the probe rod slides into the storage slot and slides to the left part of the collecting frame 20 along with the storage slot.

The first gear motor 5, the motor 15, the second electric cylinder 13, the vibration motor 18, the second gear motor 12, the first electric cylinder 8 and the PLC controller 22 of the temperature sensor chamfering device of the utility model are purchased on the market, and a person skilled in the art only needs to install and operate according to the attached instruction manual without the creative labor of the person skilled in the art.

The foregoing is merely a preferred embodiment of the present utility model, and it should be noted that it will be apparent to those skilled in the art that modifications and variations can be made without departing from the technical principles of the present utility model, and these modifications and variations should also be regarded as the scope of the utility model.

Claims (7)

1. The utility model provides a temperature sensor chamfer processingequipment, its characterized in that, includes loading attachment, fixing device, chamfer device, collection device, storage device and auxiliary device, and fixing device installs on loading attachment, and chamfer device installs on loading attachment, and collection device installs on chamfer device, and storage device installs in loading attachment, and auxiliary device installs on loading attachment.

2. The chamfering device for the temperature sensor according to claim 1, characterized in that the feeding device comprises a vibrating disc (1), a processing box (2), a top plate (3), a door frame (4), a first gear motor (5) and a toggle soft plate (6), wherein the processing box (2) is connected to the right end face of the vibrating disc (1), the top plate (3) is arranged on the upper portion in the processing box (2), a feeding groove is arranged on the upper left portion of the upper end face of the top plate (3), a discharging hole is arranged on the right portion of the upper end face of the top plate (3), the feeding groove extends rightwards to be connected with the discharging hole, the door frame (4) is arranged on the right portion of the upper end face of the vibrating disc (1), the first gear motor (5) is arranged at the rear portion of the upper end face of the door frame (4), the output end of the first gear motor (5) penetrates through the lower end face of the door frame (4) to the lower side of the door frame (4), and a plurality of groups of toggle soft plates (6) are arranged on the output end of the first gear motor (5).

3. The chamfering device for temperature sensors according to claim 2, characterized in that the fixing device comprises a receiving hopper (7), a first electric cylinder (8), clamping jaws (9), a rotating shaft (10), a baffle plate (11) and a second gear motor (12), wherein front and rear end surfaces of the receiving hopper (7) are respectively connected with front and rear end surfaces in the processing box (2), the receiving hopper (7) is positioned at the lower side of a discharge hole in the top plate (3), a group of first electric cylinders (8) are respectively arranged at the left and right sides of the lower side surface of the receiving hopper (7), moving ends of the first electric cylinders (8) respectively penetrate through the side surface of the receiving hopper (7) to enter the inside of the receiving hopper (7) to be connected with the clamping jaws (9), front and rear end surfaces of the rotating shaft (10) are respectively connected with front and rear end surfaces in the processing box (2), the baffle plate (11) is connected on the side surface of the rotating shaft (10), the second gear motor (12) is arranged on the front end surface of the processing box (2), and the output end surface of the second gear motor (12) penetrates through the front and rear end surface of the processing box (2).

4. A temperature sensor chamfering device as claimed in claim 2, characterized in that the chamfering device comprises a second electric cylinder (13), a lifting box (14), a motor (15) and a cutter head (16), the second electric cylinder (13) is mounted on the right part of the inner end surface of the processing box (2), the lifting box (14) is connected to the moving end of the second electric cylinder (13), the motor (15) is mounted on the upper end surface in the lifting box (14), and the output end of the motor (15) extends to the upper side of the lifting box (14) through the upper end surface of the lifting box (14) to be connected with the cutter head (16).

5. The chamfering processing apparatus for temperature sensor according to claim 4, characterized in that the collecting means comprises a collecting box (17), a vibrating motor (18) and a storage bin (19), the upper end face edge of the lifting box (14) is provided with a chamfer, the collecting box (17) is installed on the upper side face of the lifting box (14), the vibrating motor (18) is installed on the side face of the collecting box (17), the storage bin (19) is installed on the right portion of the lower end face of the processing box (2), and the input end of the storage bin (19) is communicated with the bottom inside the collecting box (17) through a hose.

6. The chamfering device for temperature sensors according to claim 2, characterized in that the material storage device comprises a collecting frame (20) and a supporting rod (21), the collecting frame (20) is connected to the inner bottom end face of the processing box (2) through the supporting rod (21), the right part of the collecting frame (20) is lifted upwards, a material storage slot is arranged in the middle of the collecting frame (20), chamfers are arranged on the left and right sides of the upper end face of the material storage slot, and the right part of the collecting frame (20) is positioned on the left lower side of the baffle plate (11) in a horizontal state.

7. A temperature sensor chamfering apparatus as set forth in claim 2, characterized in that the auxiliary means comprises a PLC controller (22), an observation window (23) and a sealing door (24), the PLC controller (22) is mounted on the front end face of the processing box (2), the observation window (23) is opened on the right part of the front end face of the processing box (2), and the sealing door (24) is mounted on the lower part of the front end face of the processing box (2).