CN116499740B - Matching degree detection device for gear machining - Google Patents

Abstract

The application provides a matching degree detection device for gear machining, which belongs to the technical field of gear machining and comprises a base, a first driving assembly, a second driving assembly, clamping assemblies, an adjusting assembly and detection assemblies, wherein two groups of clamping assemblies are oppositely distributed on the upper part of the base and are used for respectively clamping two groups of gears to be tested, and the first driving assembly is arranged in the base and is used for driving the two groups of clamping assemblies to move in opposite directions. Compared with the prior art, the embodiment of the application automatically adjusts the angles of the two groups of gears to be detected in the opposite movement process through the adjusting component, so that the two groups of gears to be detected can accurately enter the meshing state after being contacted, the phenomenon that teeth of the two groups of gears to be detected are propped against each other due to angle deviation is avoided, meanwhile, the gears are not required to be manually adjusted, and the detection efficiency in the gear meshing degree detection process and the safety in the detection process are improved.

Description

Matching degree detection device for gear machining

Technical Field

The application belongs to the technical field of gear machining, and particularly relates to a matching degree detection device for gear machining.

Background

The gears are important parts in mechanical equipment, and the quality of the processing quality of the gears can directly influence the vibration noise, the reliability and the like of an equipment assembly, so that the meshing degree between two groups of gears needs to be detected after the two groups of gears to be used are processed, and whether the two groups of gears are matched is judged.

In the prior art, the detection of the meshing degree between two groups of gears is mostly to place the two groups of gears on two sides of a detection table respectively, then control the two groups of gears to move in opposite directions, so that the two groups of gears are in contact with each other and enter a meshing state, then the situation that the teeth of the two groups of gears are in contact with each other possibly occurs due to the difference of the arrangement angles of the two groups of gears, so that the two groups of gears cannot be smoothly meshed, and therefore, the angle of one group of gears needs to be manually adjusted when the two groups of gears are in contact, the time and the labor are consumed when the angle of the gears is manually adjusted, the hand of a human body is easily clamped, and the safety cannot be ensured.

Disclosure of Invention

Aiming at the defects of the prior art, the embodiment of the application aims to provide a matching degree detection device for gear processing.

In order to solve the technical problems, the application provides the following technical scheme:

a matching degree detection device for gear processing comprises a base, a first driving component, a second driving component, a clamping component, an adjusting component and a detection component,

two groups of clamping assemblies are oppositely distributed on the upper part of the base and are used for respectively clamping two groups of gears to be tested,

the first driving component is arranged in the base and is used for driving the two groups of clamping components to move in opposite directions,

the adjusting component is arranged on the upper part of the base and is positioned between the two groups of clamping components, when the two groups of clamping components move in opposite directions, the adjusting component is used for adjusting the angles of the two groups of gears to be tested, so that the two groups of gears to be tested can enter a meshing state when contacting,

the detection component is arranged at one side of one group of clamping components, when two groups of gears to be detected are contacted and enter a meshing state, the detection component is used for detecting the meshing degree of the two groups of gears to be detected,

one end of the second driving component is connected with the base, the other end of the second driving component is connected with one group of clamping components, and when two groups of gears to be tested are contacted and enter a meshing state, the second driving component is used for driving the gears to be tested clamped by the clamping components to rotate.

As a further improvement of the application: the two groups of clamping components have the same structure and comprise a first U-shaped seat, a post rod, a pressing plate and a screw rod,

the post is rotationally installed on the inside left side wall of first U type seat, the screw rod runs through first U type seat right side wall and with first U type seat screw thread fit, the clamp plate rotates and sets up the screw rod is located the inside one end of first U type seat, the screw rod is located the outside one end of first U type seat is fixed to be provided with the handle, the clamp plate with the post relative distribution.

As a further improvement of the application: the upper wall of the base is provided with a chute,

the first driving component comprises a motor, a rotating shaft, a threaded sleeve and a threaded section,

the threaded sleeve is provided with two groups, the bottoms of the two groups of the first U-shaped seats are fixedly provided with connecting rods, one ends of the two groups of connecting rods, which are far away from the corresponding first U-shaped seats, extend from the sliding groove to the inside of the base and are respectively connected with the two groups of the threaded sleeve,

the motor is fixedly installed on the inner wall of the base, two groups of thread sections are arranged outside the rotating shaft, the two groups of thread sections are opposite in rotation direction, one end of the rotating shaft is connected with the output end of the motor, and the other end of the rotating shaft penetrates through the two groups of thread sleeves and is in threaded fit with the two groups of thread sleeves through the two groups of thread sections.

As a further improvement of the application: the base upper portion is fixed and is provided with the guide rail, two sets of the guide rail groove with guide rail looks adaptation has all been seted up to first U type seat bottom.

As a still further improvement of the application: the adjusting component comprises a top plate and a plurality of tooth plates arranged at the bottom of the top plate,

the tooth plates are distributed at linear intervals along the length direction of the top plate, and two tooth plates positioned at the most edge are made of elastic materials.

As a still further improvement of the application: a supporting plate is fixedly arranged at the edge of the upper part of the base,

the second driving component comprises a first elastic piece and a rope body,

one end of the rope body is wound outside the post rod, the other end of the rope body is connected with the first elastic piece, one end of the first elastic piece, which is far away from the rope body, is connected with the supporting plate and is used for providing elastic tension for the rope body,

the bottom of the top plate is also fixedly provided with a second U-shaped seat which extends into the base and is connected with the inner wall of the base through a second elastic piece, the second elastic piece is used for providing elastic support for the second U-shaped seat,

and a cam is fixedly arranged outside the rotating shaft and is attached to the second U-shaped seat.

As a still further improvement of the application: the detection assembly comprises a support rod fixedly arranged on one side of one group of the first U-shaped seat and a camera arranged on one side of the support rod.

Compared with the prior art, the application has the beneficial effects that:

in the embodiment of the application, when the meshing degree of the two groups of gears to be detected is required to be detected, the two groups of gears to be detected can be respectively clamped by the two groups of clamping assemblies, then the two groups of clamping assemblies are driven to move in opposite directions by the first driving assembly, and then the two groups of gears to be detected are driven to move in opposite directions.

Drawings

FIG. 1 is a schematic diagram of a gear processing matching degree detection device;

FIG. 2 is a schematic perspective view of a gear machining matching degree detection device;

FIG. 3 is a schematic perspective view of a device for detecting the degree of matching for gear machining;

FIG. 4 is an enlarged schematic view of area A of FIG. 1;

in the figure: 10-base, 101-chute, 102-guide rail, 103-backup pad, 20-first drive assembly, 201-motor, 202-pivot, 203-threaded sleeve, 204-threaded section, 205-cam, 30-second drive assembly, 301-first elastic member, 302-rope, 40-clamping assembly, 401-handle, 402-first U-shaped seat, 403-post, 404-clamp plate, 405-screw, 50-adjusting assembly, 501-top plate, 502-tooth plate, 503-second U-shaped seat, 504-second elastic member, 60-detecting assembly.

Detailed Description

The technical scheme of the application is further described in detail below with reference to the specific embodiments.

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

Referring to fig. 1, the embodiment provides a matching degree detection device for gear processing, which comprises a base 10, a first driving component 20, a second driving component 30, a clamping component 40, an adjusting component 50 and a detection component 60, wherein two groups of clamping components 40 are relatively distributed on the upper portion of the base 10, the two groups of clamping components 40 are used for respectively clamping two groups of gears to be detected, the first driving component 20 is installed inside the base 10 and is used for driving the two groups of clamping components 40 to move in opposite directions, the adjusting component 50 is arranged on the upper portion of the base 10 and is positioned between the two groups of clamping components 40, when the two groups of clamping components 40 move in opposite directions, the adjusting component 50 is used for adjusting the angles of the two groups of gears to be detected, so that the two groups of gears to be detected can enter an engaged state when contacting, the detection component 60 is arranged on one side of the clamping components 40, when the two groups of gears to be detected contact and enter the engaged state, the detection component 60 is used for detecting the engagement degree of the two groups of gears to be detected, the second driving component 30 is arranged on the other side of the clamping component, and the other end of the clamping component 40 is used for driving the two groups of gears to enter the engaged state when the two groups of gears to be detected, and the two groups of gears to be detected are contacted with one another end of the clamping component 30, and the two groups of gears to be detected are driven by the driving component 30 to enter the engaged state.

When the meshing degree of the two groups of gears to be tested is required to be tested, the two groups of clamping assemblies 40 can be utilized to clamp the two groups of gears to be tested respectively, then the first driving assembly 20 is utilized to drive the two groups of clamping assemblies 40 to move in opposite directions, and further drive the two groups of gears to be tested to move in opposite directions, in the process, the angle of the two groups of gears to be tested is adjusted through the adjusting assembly 50, so that the two groups of gears to be tested can enter a meshing state when being contacted, after the two groups of gears to be tested enter the meshing state, the meshing degree of the two groups of gears to be tested is tested by the detecting assembly 60, and when the two groups of gears to be tested enter the meshing state, one group of gears to be tested can be driven to rotate through the second driving assembly 30, and then the other group of gears to be tested can be driven to synchronously rotate through the meshing effect of the two groups of gears to be tested, and thus, the different meshing positions of the two groups of gears to be tested can be adjusted to one side of the detecting assembly 60, and the detection of the meshing degree of the two groups of gears to be tested to different positions is realized.

Referring to fig. 1 and 2, in one embodiment, the two sets of clamping assemblies 40 have the same structure and each include a first U-shaped seat 402, a post 403, a pressing plate 404 and a screw 405, the post 403 is rotatably mounted on the left side wall inside the first U-shaped seat 402, the screw 405 penetrates through the right side wall of the first U-shaped seat 402 and is in threaded engagement with the first U-shaped seat 402, the pressing plate 404 is rotatably disposed at one end of the screw 405 located inside the first U-shaped seat 402, and a handle 401 is fixedly disposed at one end of the screw 405 located outside the first U-shaped seat 402, and the pressing plate 404 and the post 403 are distributed relatively.

Through arranging two sets of gears to be tested inside two sets of first U type seats 402 respectively, then rotate handle 401, and then drive screw 405 and rotate, utilize screw 405 and the screw thread cooperation of first U type seat 402 in order to drive clamp plate 404 to the inboard removal of first U type seat 402, and then compress tightly the gear to be tested in pole 403 one end, realize the centre gripping location of gear to be tested.

Referring to fig. 1 and 2, in an embodiment, the upper wall of the base 10 is provided with a chute 101, the first driving assembly 20 includes a motor 201, a rotating shaft 202, a threaded sleeve 203 and a threaded section 204, the threaded sleeve 203 is provided with two groups, the bottoms of the two groups of the first U-shaped seats 402 are fixedly provided with connecting rods, one ends of the two groups of connecting rods, which are far away from the corresponding first U-shaped seats 402, extend from the chute 101 to the inside of the base 10 and are respectively connected with the two groups of threaded sleeve 203, the motor 201 is fixedly mounted on the inner wall of the base 10, the threaded section 204 is provided with two groups of threaded sections 204 outside the rotating shaft 202, one ends of the rotating shaft 202 are connected with the output end of the motor 201, and the other ends of the threaded sections penetrate through the two groups of threaded sleeve 203 and are respectively in threaded fit with the two groups of threaded sleeve 203 through the two groups of threaded section 204.

After the two sets of gears to be tested are respectively clamped inside the two sets of first U-shaped seats 402, the motor 201 drives the rotating shaft 202 to rotate, and the two sets of threaded sleeves 203 can be driven to move in opposite directions by utilizing the threaded cooperation of the two sets of threaded sections 204 and the two sets of threaded sleeves 203, so as to drive the two sets of first U-shaped seats 402 and the gears to be tested clamped inside the two sets of first U-shaped seats 402 to move in opposite directions.

Referring to fig. 1 and 2, in one embodiment, a guide rail 102 is fixedly disposed on an upper portion of the base 10, and guide rail grooves (not shown) adapted to the guide rail 102 are formed on bottoms of the two sets of the first U-shaped seats 402.

The bottoms of the two first U-shaped seats 402 are slidably matched with the guide rail 102 through the guide rail groove, so that the two first U-shaped seats 402 can be driven to move in opposite directions through the threaded matching of the two sets of threaded sections 204 and the two sets of threaded sleeves 203 when the rotating shaft 202 rotates.

Referring to fig. 1, 3 and 4, in one embodiment, the adjusting assembly 50 includes a top plate 501 and a plurality of teeth 502 disposed at the bottom of the top plate 501, wherein the teeth 502 are linearly spaced along the length direction of the top plate 501, and two teeth 502 at the edge are made of an elastic material.

When two groups of gears to be tested move in opposite directions, teeth of the two groups of gears to be tested can be contacted with the most marginal tooth piece 502 in advance, and as the most marginal tooth piece 502 is made of elastic materials, when the teeth of the gears to be tested can just enter a meshing state with the most marginal tooth piece 502, the most marginal tooth piece 502 can push the gears to be tested to rotate, the gears to be tested can further mesh with a plurality of subsequent tooth pieces 502 and be pushed to rotate by a plurality of subsequent tooth pieces 502, the post 403 and the pressing plate 404 can be driven to synchronously rotate when the gears to be tested rotate until the two groups of gears to be tested are contacted, and the advancing distance and the rotating angle of the two groups of gears to be tested along the plurality of tooth pieces 502 are certain, so that the two groups of gears to be tested can accurately enter the meshing state when the two groups of gears to be tested are contacted; when the teeth of the gear to be measured are in an abutting state with the edge-most tooth plate 502, the edge-most tooth plate 502 can generate adaptive compression deformation and push the gear to be measured to rotate at the same time, so that the gear to be measured can be meshed with a plurality of subsequent tooth plates 502 and pushed to rotate by a plurality of subsequent tooth plates 502 until the two groups of gears to be measured are contacted, and the two groups of gears to be measured can also accurately enter the meshed state.

In one embodiment, the two sets of teeth 502 at the extreme edge may be made of rubber, or may be made of silicone, without limitation.

Referring to fig. 1 and 2, in one embodiment, the upper edge of the base 10 is fixedly provided with a support plate 103, the second driving assembly 30 includes a first elastic member 301 and a rope 302, one end of the rope 302 is wound around the outside of the post 403, the other end of the rope 302 is connected to the first elastic member 301, one end of the first elastic member 301 away from the rope 302 is connected to the support plate 103, for providing elastic tension to the rope 302, the bottom of the top plate 501 is further fixedly provided with a second U-shaped seat 503, the second U-shaped seat 503 extends into the base 10 and is connected to the inner wall of the base 10 through a second elastic member 504, the second elastic member 504 is used for providing elastic support to the second U-shaped seat 503, and the outside of the rotating shaft 202 is fixedly provided with a cam 205, and the cam 205 is attached to the second U-shaped seat 503.

When the gears to be tested are meshed with the tooth plates 502 to drive the post 403 to rotate, the post 403 can pull and roll the rope 302, so that the first elastic piece 301 stretches, when the rotating shaft 202 rotates to drive the two groups of gears to be tested to move in opposite directions, the cam 205 can be driven to rotate synchronously, when the two groups of gears to be tested are contacted and enter a meshed state, the rotation of the cam 205 can push the second U-shaped seat 503 to move upwards, so as to drive the top plate 501 to move upwards, a plurality of tooth plates 502 at the bottom of the top plate 501 are separated from the two groups of gears to be tested, then the first elastic piece 301 can provide elastic tension for the rope 302, the rope 302 transmits the tension to the post 403 to drive the post 403 to rotate reversely and unwind the rope 302, and when the post 403 rotates reversely, the gears to be tested pressed at one end of the post can be driven to rotate synchronously, and then drive the other group of gears to be tested to rotate synchronously through the meshing effect of the other group of gears to be tested to adjust different meshing positions of the two groups of gears to one side of the detection assembly 60, so that detection of meshing degrees of different positions of the two groups of gears to be tested is realized.

Referring to fig. 1 and 2, in one embodiment, the detecting assembly 60 includes a supporting rod fixedly disposed on one side of the first U-shaped seat 402 and a camera disposed on one side of the supporting rod, and when two sets of gears to be detected enter a meshing state, the camera is used to collect images of meshing positions of the two sets of gears to be detected so as to reflect meshing degree information of the two sets of gears to be detected.

In one embodiment, the first elastic member 301 and the second elastic member 504 may be springs or metal elastic sheets, which is not limited herein.

In the embodiment of the application, when the meshing degree of two groups of gears to be measured is required to be detected, two groups of clamping assemblies 40 can be utilized to clamp the two groups of gears to be measured respectively, then the first driving assembly 20 is utilized to drive the two groups of clamping assemblies 40 to move towards each other, and then the two groups of gears to be measured are driven to move towards each other, in the process, the angle of the two groups of gears to be measured is adjusted through the adjusting assembly 50, so that the two groups of gears to be measured can enter a meshing state when contacting, after the two groups of gears to be measured enter the meshing state, the detecting assembly 60 is utilized to detect the meshing degree of the two groups of gears to be measured, and when the two groups of gears to be measured enter the meshing state, one group of gears to be measured can be driven to rotate through the meshing effect of the second driving assembly 30 with the other group of gears to drive the other group of gears to rotate synchronously, so that different meshing positions of the two groups of gears to be measured can be adjusted to one side of the detecting assembly 60, compared with the prior art, the angle of the two groups of gears to be measured in the different positions of the two groups of gears to be measured can be automatically adjusted, after the two groups of gears to be measured in the opposite directions can enter the meshing state, the meshing degree can be accurately adjusted, and the meshing degree of the two groups of gears to be measured can enter the gears to be measured, and the meshing state can be prevented, and the phenomenon that the meshing state can be detected, can be prevented, and the phenomenon that the meshing degree can occur, can be detected, and the phenomenon can be detected.

While the preferred embodiments of the present application have been described in detail, the present application is not limited to the above embodiments, and various changes can be made without departing from the spirit of the present application within the knowledge of those skilled in the art.

Claims (3)

1. A matching degree detection device for gear processing is characterized by comprising a base, a first driving component, a second driving component, a clamping component, an adjusting component and a detection component,

two groups of clamping assemblies are oppositely distributed on the upper part of the base and are used for respectively clamping two groups of gears to be tested,

the first driving component is arranged in the base and is used for driving the two groups of clamping components to move in opposite directions,

the adjusting component is arranged on the upper part of the base and is positioned between the two groups of clamping components, when the two groups of clamping components move in opposite directions, the adjusting component is used for adjusting the angles of the two groups of gears to be tested, so that the two groups of gears to be tested can enter a meshing state when contacting,

the detection component is arranged at one side of one group of clamping components, when two groups of gears to be detected are contacted and enter a meshing state, the detection component is used for detecting the meshing degree of the two groups of gears to be detected,

one end of the second driving component is connected with the base, the other end of the second driving component is connected with one group of clamping components, when two groups of gears to be tested are contacted and enter a meshed state, the second driving component is used for driving the gears to be tested clamped by the group of clamping components to rotate,

the two groups of clamping components have the same structure and comprise a first U-shaped seat, a post rod, a pressing plate and a screw rod,

the post rod is rotatably arranged on the left side wall inside the first U-shaped seat, the screw rod penetrates through the right side wall of the first U-shaped seat and is in threaded fit with the first U-shaped seat, the pressing plate is rotatably arranged at one end of the screw rod positioned inside the first U-shaped seat, the handle is fixedly arranged at one end of the screw rod positioned outside the first U-shaped seat, the pressing plate and the post rod are distributed relatively,

the upper wall of the base is provided with a chute,

the first driving component comprises a motor, a rotating shaft, a threaded sleeve and a threaded section,

the threaded sleeve is provided with two groups, the bottoms of the two groups of the first U-shaped seats are fixedly provided with connecting rods, one ends of the two groups of connecting rods, which are far away from the corresponding first U-shaped seats, extend from the sliding groove to the inside of the base and are respectively connected with the two groups of the threaded sleeve,

the motor is fixedly arranged on the inner wall of the base, two groups of thread sections are arranged outside the rotating shaft, the two groups of thread sections are opposite in rotation direction, one end of the rotating shaft is connected with the output end of the motor, the other end of the rotating shaft penetrates through the two groups of thread sleeves and is respectively in threaded fit with the two groups of thread sleeves through the two groups of thread sections,

the adjusting component comprises a top plate and a plurality of tooth plates arranged at the bottom of the top plate,

the plurality of tooth plates are distributed at linear intervals along the length direction of the top plate, the two tooth plates positioned at the most edge are made of elastic materials,

a supporting plate is fixedly arranged at the edge of the upper part of the base,

the second driving component comprises a first elastic piece and a rope body,

one end of the rope body is wound outside the post rod, the other end of the rope body is connected with the first elastic piece, one end of the first elastic piece, which is far away from the rope body, is connected with the supporting plate and is used for providing elastic tension for the rope body,

the bottom of the top plate is also fixedly provided with a second U-shaped seat which extends into the base and is connected with the inner wall of the base through a second elastic piece, the second elastic piece is used for providing elastic support for the second U-shaped seat,

and a cam is fixedly arranged outside the rotating shaft and is attached to the second U-shaped seat.

2. The matching degree detection device for gear machining according to claim 1, wherein guide rails are fixedly arranged on the upper portion of the base, and guide rail grooves matched with the guide rails are formed in the bottoms of the two groups of the first U-shaped bases.

3. The device for detecting the degree of matching for gear machining according to claim 1, wherein the detecting assembly comprises a support rod fixedly arranged on one side of one group of the first U-shaped seats and a camera arranged on one side of the support rod.