CN118341697A - Cutter check out test set - Google Patents

Abstract

The invention discloses cutter detection equipment, which relates to the technical field of cutter processing and comprises a working platform, wherein the top end of the working platform is sequentially connected with a driving assembly, a detection platform, a detection assembly and a control assembly, a cutter is arranged between the driving assembly and the detection platform, one end of the working platform is externally provided with a feeding frame, a qualified discharging frame and a disqualified discharging frame, the driving assembly comprises an L-shaped rod and a first driving motor, the bottom of the L-shaped rod is provided with a first bearing seat, the outer surface of the L-shaped rod is connected with a driven gear, the output end of the first driving motor is connected with a driving gear, the driving gear is in meshed connection with the driven gear, the cutter inside the feeding frame can be automatically taken out through the driving assembly and moved to the detection platform to wait for detection, and during detection, the second driving motor drives the cutter to rotate for auxiliary detection, and the detected cutter is respectively placed into the qualified discharging frame and the disqualified discharging frame according to qualification.

Description

Cutter check out test set

Technical Field

The invention relates to the technical field of cutter machining, in particular to cutter detection equipment.

Background

After the cutter is machined, the cutting edge size of the cutter needs to be detected so as to judge whether the cutter meets the requirements of the industry standard, and in order to detect the cutting edge size of the cutter more conveniently, a kitchen knife cutting edge geometric shape detection device and a detection method of the prior published patent CN113588477A judge whether the cutting edge size of the cutter is qualified or not based on a digital optical microscope in the technical content of the published patent;

The detection equipment with the structure can only detect one group of cutting edges of the cutter in one detection program, and can not combine detection data of a plurality of groups of cutting edges to carry out comparison and analysis, thereby promoting lower overall detection precision of the size of the cutting edges of the cutter.

Disclosure of Invention

Aiming at the defects of the prior art, the invention provides cutter detection equipment, which solves the problems in the background art.

In order to achieve the above purpose, the invention is realized by the following technical scheme: the utility model provides a cutter check out test set, includes work platform, work platform's top has connected gradually drive assembly, testing platform, testing assembly and control assembly, be equipped with the cutter between drive assembly and the testing platform, work platform's one end outside is equipped with work or material rest, qualified work or material rest and unqualified work or material rest down.

Preferably, the drive assembly includes L type pole and first driving motor, the bottom of L type pole is equipped with first bearing frame, the surface connection of L type pole has driven gear, first driving motor's output is connected with the driving gear, and driving gear and driven gear are the meshing and are connected, the top free end of L type pole is connected with L template, the surface mounting of L template has electric putter, electric putter's flexible end is connected with the motor frame, the internally mounted of motor frame has second driving motor, the output of second driving motor passes the bottom of motor frame and is connected with the connecting seat, the bottom center scarf joint of connecting seat has the electro-magnet.

Preferably, the bottom of first driving motor and first bearing frame all links to each other with work platform, testing platform, material loading frame, qualified unloading frame and unqualified unloading frame are circumference form and equidistance distribution around the bottom of L type pole, the electro-magnet is located testing platform directly over, the cutter is located the bottom center department of electro-magnet.

Preferably, the detection platform comprises a base, a second bearing seat is arranged at the center of the top end of the base, a rotating rod is connected to the inner part of the second bearing seat, and a turntable is connected to the top end of the rotating rod.

Preferably, the detection assembly comprises a U-shaped frame, a screw rod and a guide rod are arranged on the side wall of the top of the U-shaped frame, bearings are arranged at the joints of the two ends of the U-shaped frame and the screw rod, a first servo motor is arranged on the outer side face of the U-shaped frame, the output end of the first servo motor is connected with one end of the screw rod, a sliding table is connected with the outer parts of the screw rod and the guide rod together, the screw rod and the sliding table are in threaded rotation connection, and the guide rod and the sliding table are in sliding connection.

Preferably, the top center of slip table is equipped with the rack, the outside of rack is equipped with removes the frame, two sets of spouts have been seted up to the bottom side of rack, the bottom medial surface of removing the frame is equipped with two sets of sliders, and two sets of sliders are located two sets of spouts inside respectively, the side-mounting of removing the frame has the second servo motor, the output of second servo motor passes the lateral wall of removing the frame and is connected with the fine setting gear, fine setting gear and rack are the meshing connection, self-recovery type linear displacement sensor is installed on the top of removing the frame, self-recovery type linear displacement sensor's detection end is equipped with the pulley.

Preferably, the control assembly comprises a case, a controller, a data comparison module, an electronic counter module and a wireless transmission module are arranged in an inner cavity of the case, an alarm is installed on the side face of the case, a case cover is connected to the top end of the case, and the data comparison module, the electronic counter module, the wireless transmission module and the alarm are respectively in signal connection with the controller.

Preferably, the controller is in signal connection with the first driving motor, the electric push rod, the second driving motor, the electromagnet, the first servo motor, the second servo motor and the self-recovery linear displacement sensor respectively.

Advantageous effects

The invention provides a tool detection device. Compared with the prior art, the method has the following beneficial effects:

The pulley drives the detection end of the self-recovery linear displacement sensor to reciprocate through rotation of the cutter, so that the maximum numerical value in each reciprocation is recorded, the outer diameter sizes of a plurality of groups of cutter edges of the cutter are collected, collected data are converted into signal data and transmitted to the controller, the controller transmits the signal data to the data comparison module, the plurality of groups of data are analyzed, if the difference value between the plurality of groups of data is larger than the standard difference value of the cutter, the cutter is unqualified, the controller starts an alarm to remind, if the difference value between the plurality of groups of data is smaller than or equal to the standard difference value, the alarm does not work, the controller starts the electronic counter module to count at the moment, and the counted times of the electronic counter module are transmitted to the PC end in real time through the wireless transmission module.

Drawings

FIG. 1 is a schematic diagram of the structure of the present invention;

FIG. 2 is a schematic diagram of a driving assembly according to the present invention;

FIG. 3 is a schematic structural diagram of the detection platform according to the present invention;

FIG. 4 is a schematic diagram of a detecting assembly according to the present invention;

FIG. 5 is a schematic diagram of a control assembly according to the present invention;

Fig. 6 is a schematic frame diagram of the present invention.

In the figure: 1. a working platform; 2. a drive assembly; 21. an L-shaped rod; 22. a first driving motor; 23. a first bearing seat; 24. a driven gear; 25. a drive gear; 26. an L-shaped plate; 27. an electric push rod; 28. a motor frame; 29. a second driving motor; 210. a connecting seat; 211. an electromagnet; 3. a detection platform; 31. a base; 32. a second bearing seat; 33. a rotating lever; 34. a turntable; 4. a detection assembly; 41. a U-shaped frame; 42. a screw rod; 43. a guide rod; 44. a bearing; 45. a first servo motor; 46. a sliding table; 47. a rack; 48. a moving frame; 49. a second servo motor; 410. fine tuning the gear; 411. a self-restoring linear displacement sensor; 412. a pulley; 413. a chute; 414. a slide block; 5. a control assembly; 51. a chassis; 52. a controller; 53. a data comparison module; 54. an electronic counter module; 55. a wireless transmission module; 56. an alarm; 57. a case cover; 6. a cutter; 7. a feeding frame; 8. qualified blanking frames; 9. and (5) discharging the material frame unqualified.

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. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

Referring to fig. 1, the present invention provides a technical solution: the utility model provides a cutter check out test set, includes work platform 1, and work platform 1's top has connected gradually drive assembly 2, testing platform 3, testing assembly 4 and control assembly 5, is equipped with cutter 6 between drive assembly 2 and the testing platform 3, and work platform 1's one end outside is equipped with work or material rest 7, qualified unloading frame 8 and unqualified unloading frame 9.

Referring to fig. 2, the driving assembly 2 includes an L-shaped rod 21 and a first driving motor 22, a first bearing seat 23 is disposed at the bottom of the L-shaped rod 21, a driven gear 24 is connected to the outer surface of the L-shaped rod 21, an output end of the first driving motor 22 is connected to a driving gear 25, the driving gear 25 and the driven gear 24 are in meshed connection, a top free end of the L-shaped rod 21 is connected to an L-shaped plate 26, an electric push rod 27 is mounted on a surface of the L-shaped plate 26, a motor frame 28 is connected to a telescopic end of the electric push rod 27, a second driving motor 29 is mounted inside the motor frame 28, an output end of the second driving motor 29 passes through the bottom of the motor frame 28 and is connected to a connecting seat 210, an electromagnet 211 is embedded in the bottom center of the connecting seat 210, the bottom ends of the first driving motor 22 and the first bearing seat 23 are all connected to the working platform 1, the detecting platform 3, the feeding frame 7, the qualified blanking frame 8 and the unqualified blanking frame 9 are distributed in a circumference and equidistance around the bottom of the L-shaped rod 21, the electromagnet 211 is located right above the detecting platform 3, and the cutter 6 is located at the center of the electromagnet 211.

In actual use, the electromagnet 211 is located right above the feeding frame 7 as a starting point, the electric push rod 27 is in telescopic motion, the electromagnet 211 adsorbs the cutter 6 inside the feeding frame 7 and returns to the original position, then the first driving motor 22 drives the driving gear 25 to rotate 90 degrees clockwise, the driven gear 24 drives the L-shaped rod 21 to rotate 90 degrees anticlockwise through the first bearing seat 23, the electromagnet 211 carries the cutter 6 to move right above the detection platform 3, the electromagnet 211 is driven to move downwards through the extension of the electric push rod 27, the lower surface of the cutter 6 is attached to the top end of the detection platform 3, the second driving motor 29 is driven to rotate for detection, after detection is finished, the second driving motor 29 stops working, the electric push rod 27 contracts to drive the electromagnet 211 and the cutter 6 to return to the original position, at this time, if the cutter 6 is detected to be qualified, the first driving motor 22 rotates 90 degrees clockwise, the cutter 6 is located right above the detection frame 8, the electric push rod 27 is in telescopic motion, the cutter 6 is placed inside the qualified frame 8, the cutter 6 is driven by the electric push rod 27 to move downwards, if the electric push rod 27 is not detected, the cutter 6 is not detected to be right above the frame 9, the cutter 6 is driven to move right time, the cutter 9 is driven by the electric push rod 27 to move right, and the cutter 9 is not qualified, and the cutter 9 is driven to move right time, and the cutter 9 is not detected.

Referring to fig. 3, the detection platform 3 includes a base 31, a second bearing seat 32 is installed at the center of the top end of the base 31, a rotating rod 33 is connected to the interior of the second bearing seat 32, and a turntable 34 is connected to the top end of the rotating rod 33.

In actual use, the rotating rod 33 rotates through the second bearing seat 32, so as to drive the turntable 34 to rotate.

Referring to fig. 4, the detecting component 4 includes a u-shaped frame 41, a screw rod 42 and a guide rod 43 are disposed on a top side wall of the u-shaped frame 41, bearings 44 are disposed at joints of two ends of the u-shaped frame 41 and the screw rod 42, a first servo motor 45 is mounted on an outer side surface of the u-shaped frame 41, an output end of the first servo motor 45 is connected with one end of the screw rod 42, a sliding table 46 is jointly connected with an outer portion of the screw rod 42 and an outer portion of the guide rod 43, the screw rod 42 and the sliding table 46 are in threaded rotation connection, the guide rod 43 and the sliding table 46 are in sliding connection, a rack 47 is disposed at a top center of the sliding table 46, a moving frame 48 is disposed on an outer portion of the rack 47, two groups of sliding grooves 413 are disposed on a bottom side surface of the rack 47, two groups of sliding blocks 414 are disposed on a bottom inner side surface of the moving frame 48, the two groups of sliding blocks 414 are disposed inside the two groups of sliding grooves 413 respectively, a second servo motor 49 is mounted on a side surface of the moving frame 48, an output end of the second servo motor 49 penetrates through a side wall of the moving frame 48 and is connected with a fine adjustment gear 410, the fine adjustment gears 410 and 47 are in meshed connection, a self-recovery type linear displacement sensor 411 is mounted on a top of the moving frame 48, and a self-recovery type linear displacement sensor is disposed at a linear displacement sensor 412.

In actual use, the detection assembly 4 drives the screw rod 42 to rotate forward through the first servo motor 45, so that the sliding table 46 drives the self-recovery type linear displacement sensor 411 to be close to the cutter 6, the second servo motor 49 drives the fine adjustment gear 410 to rotate anticlockwise, then the moving frame 48 drives the self-recovery type linear displacement sensor 411 and the pulley 412 to slowly move towards the cutter 6 outside the rack 47 until the detection end of the self-recovery type linear displacement sensor 411 detects numerical value change through extrusion or closes the second servo motor 49, and after detection is finished, the first servo motor 45 and the second servo motor 49 reversely rotate, so that the self-recovery type linear displacement sensor 411 and the pulley 412 return to the original positions.

Referring to fig. 5-6, the control assembly 5 includes a chassis 51, a controller 52, a data comparing module 53, an electronic counter module 54 and a wireless transmission module 55 are disposed in an inner cavity of the chassis 51, an alarm 56 is installed on a side surface of the chassis 51, a case cover 57 is connected to a top end of the chassis 51, the data comparing module 53, the electronic counter module 54, the wireless transmission module 55 and the alarm 56 are respectively in signal connection with the controller 52, and the controller 52 is respectively in signal connection with the first driving motor 22, the electric push rod 27, the second driving motor 29, the electromagnet 211, the first servo motor 45, the second servo motor 49 and the self-recovery linear displacement sensor 411.

It should be noted that the working principle of the data comparing module 53 is well known in the art, and will not be described in detail herein.

When the automatic feeding device is used, firstly, the controller 52 controls the driving assembly 2 to work, so that the electric push rod 27 performs telescopic motion, the electromagnet 211 adsorbs the cutter 6 in the feeding frame 7 and returns to the original position, then the first driving motor 22 drives the driving gear 25 to rotate 90 degrees clockwise, the driven gear 24 drives the L-shaped rod 21 to rotate 90 degrees anticlockwise through the first bearing seat 23, the electromagnet 211 carries the cutter 6 to move right above the detection platform 3, and the electric push rod 27 stretches to drive the electromagnet 211 to carry the cutter 6 to move downwards, so that the lower surface of the cutter 6 is attached to the top end of the rotary table 34;

The screw rod 42 is driven to rotate forward through the first servo motor 45, the sliding table 46 drives the self-recovery type linear displacement sensor 411 to be close to the cutter 6, the second servo motor 49 drives the fine adjustment gear 410 to rotate anticlockwise, the moving frame 48 drives the self-recovery type linear displacement sensor 411 and the pulley 412 to slowly move towards the cutter 6 outside the rack 47 until the detection end of the self-recovery type linear displacement sensor 411 detects numerical value change through extrusion or the second servo motor 49 is closed;

The second driving motor 29 drives the cutter 6 to rotate, so that the pulley 412 drives the detection end of the self-recovery linear displacement sensor 411 to reciprocate, the maximum value in each reciprocation is recorded, a plurality of groups of cutter edge outer diameter sizes of the cutter 6 are collected, collected data are converted into signal data and transmitted to the controller 52, the controller 52 transmits the signal data to the data comparison module 53, the plurality of groups of data are analyzed, if the difference value between the plurality of groups of data is larger than the standard deviation value of the cutter 6, the cutter 6 is disqualified, the controller 52 starts the alarm 56 to remind, if the difference value between the plurality of groups of data is smaller than or equal to the standard deviation value, the alarm 56 does not work, the controller 52 starts the electronic counter module 54 to count at the moment, and the counted times of the electronic counter module 54 are transmitted to the PC end in real time through the wireless transmission module 55;

After the detection is finished, the first servo motor 45 and the second servo motor 49 reversely rotate to enable the self-recovery type linear displacement sensor 411 and the pulley 412 to return to the original positions, the second driving motor 29 stops working, the electric push rod 27 contracts to drive the electromagnet 211 and the cutter 6 to return to the original positions, at the moment, if the cutter 6 is detected to be qualified, the first driving motor 22 rotates clockwise by 90 degrees to enable the cutter 6 to be positioned right above the qualified blanking frame 8, the electric push rod 27 does telescopic motion to enable the cutter 6 to be positioned inside the qualified blanking frame 8, if the cutter 6 is detected to be unqualified, the first driving motor 22 rotates clockwise by 90 degrees to enable the cutter 6 to be positioned right above the unqualified blanking frame 9, the electric push rod 27 does telescopic motion to enable the cutter 6 to be positioned inside the unqualified blanking frame 9, and then the first driving motor 22 is started to drive the electromagnet 211 to move right above the upper blanking frame 7.

In this embodiment, the model of the self-restoring linear displacement sensor 411 is KTS-B-25mm, and in the above components, the structural features, the working principle and the specific circuit structure electrically connected to the outside of the self-restoring linear displacement sensor are all related art, which will not be described in detail herein.

Claims (8)

1. The utility model provides a cutter check out test set, includes work platform (1), its characterized in that, drive assembly (2), testing platform (3), testing assembly (4) and control assembly (5) have connected gradually on the top of work platform (1), be equipped with cutter (6) between drive assembly (2) and testing platform (3), the one end outside of work platform (1) is equipped with work or material rest (7), qualified work or material rest (8) and unqualified work or material rest (9).

2. The tool detection device according to claim 1, wherein the driving assembly (2) comprises an L-shaped rod (21) and a first driving motor (22), a first bearing seat (23) is arranged at the bottom of the L-shaped rod (21), a driven gear (24) is connected to the outer surface of the L-shaped rod (21), a driving gear (25) is connected to the output end of the first driving motor (22), the driving gear (25) and the driven gear (24) are in meshed connection, an L-shaped plate (26) is connected to the top free end of the L-shaped rod (21), an electric push rod (27) is arranged on the surface of the L-shaped plate (26), a motor frame (28) is connected to the telescopic end of the electric push rod (27), a second driving motor (29) is arranged inside the motor frame (28), the output end of the second driving motor (29) penetrates through the bottom of the motor frame (28) and is connected with a connecting seat (210), and an electromagnet (211) is embedded in the bottom center of the connecting seat (210).

3. The tool detection device according to claim 2, wherein the first driving motor (22) and the bottom end of the first bearing seat (23) are connected with the working platform (1), the detection platform (3), the feeding rack (7), the qualified discharging rack (8) and the unqualified discharging rack (9) are circumferentially and equidistantly distributed around the bottom of the L-shaped rod (21), the electromagnet (211) is located right above the detection platform (3), and the tool (6) is located at the center of the bottom end of the electromagnet (211).

4. A tool detection device according to claim 3, characterized in that the detection platform (3) comprises a base (31), a second bearing seat (32) is installed at the top center of the base (31), a rotating rod (33) is connected to the inside of the second bearing seat (32), and a turntable (34) is connected to the top end of the rotating rod (33).

5. The tool detection device according to claim 1, wherein the detection assembly (4) comprises a U-shaped frame (41), a screw rod (42) and a guide rod (43) are arranged on the top side wall of the U-shaped frame (41), bearings (44) are arranged at the joints of the two ends of the U-shaped frame (41) and the screw rod (42), a first servo motor (45) is arranged on the outer side surface of the U-shaped frame (41), the output end of the first servo motor (45) is connected with one end of the screw rod (42), a sliding table (46) is connected with the outer parts of the screw rod (42) and the guide rod (43) together, the screw rod (42) and the sliding table (46) are in threaded rotation connection, and the guide rod (43) and the sliding table (46) are in sliding connection.

6. The tool detection device according to claim 5, wherein a rack (47) is arranged at the center of the top end of the sliding table (46), a movable frame (48) is arranged outside the rack (47), two groups of sliding grooves (413) are formed in the side face of the bottom of the rack (47), two groups of sliding blocks (414) are arranged on the inner side face of the bottom of the movable frame (48), the two groups of sliding blocks (414) are respectively located inside the two groups of sliding grooves (413), a second servo motor (49) is mounted on the side face of the movable frame (48), the output end of the second servo motor (49) penetrates through the side wall of the movable frame (48) and is connected with a fine adjustment gear (410), the fine adjustment gear (410) is in meshed connection with the rack (47), a self-recovery linear displacement sensor (411) is mounted at the top end of the movable frame (48), and a pulley (412) is arranged at the detection end of the self-recovery linear displacement sensor (411).

7. The tool detection device according to claim 1, wherein the control assembly (5) comprises a case (51), a controller (52), a data comparison module (53), an electronic counter module (54) and a wireless transmission module (55) are arranged in an inner cavity of the case (51), an alarm (56) is installed on a side face of the case (51), a case cover (57) is connected to the top end of the case (51), and the data comparison module (53), the electronic counter module (54), the wireless transmission module (55) and the alarm (56) are respectively in signal connection with the controller (52).

8. The tool detection device according to claim 7, wherein the controller (52) is in signal connection with the first driving motor (22), the electric push rod (27), the second driving motor (29), the electromagnet (211), the first servo motor (45), the second servo motor (49) and the self-restoring linear displacement sensor (411), respectively.