CN118328862B - EPE foam cotton thickness detection device - Google Patents

Abstract

The invention discloses an EPE foam cotton thickness detection device, and relates to the field of foam cotton processing. The EPE foam cotton thickness detection device comprises a workbench, a first CCD camera and a second CCD camera are arranged on the front surface of the workbench, a conveying mechanism is arranged above the workbench, the conveying mechanism comprises a fixed frame, a transmission belt is connected to the inner wall of the fixed frame in a transmission manner, a transmission roller is arranged above the transmission belt, a plurality of limiting teeth are arranged on the peripheral wall of the transmission roller, a movable bar is arranged on the inner wall of the support frame in a sliding manner, a plurality of extrusion rollers are rotatably arranged between the two movable bars, and an extrusion spring is arranged between the movable bar and the inner top wall of the support frame. This EPE foam cotton thickness detection device, first CCD camera can take a picture and carry out thickness detection to the EPE foam cotton that does not extrude, and the second CCD camera can take a picture and carry out continuous thickness detection to the EPE foam cotton after fully extruding in succession, reaches more effective continuous detection effect.

Description

EPE foam cotton thickness detection device

Technical Field

The invention relates to the technical field of foam cotton processing, in particular to an EPE foam cotton thickness detection device.

Background

After the EPE foam cotton is processed, multiple sampling inspection, such as porosity detection, harmful substance detection, density detection, thickness detection and the like, are required to be carried out on the EPE foam cotton in different batches, wherein the thickness detection is the most common detection mode, and in order to ensure the detection regularity, the sampling inspection is carried out on the EPE foam cotton.

When the thickness of EPE foam cotton is detected, a thickness gauge is generally adopted to detect single materials, or a CCD camera is adopted to carry out photographing detection on moving EPE foam cotton, when the thickness gauge is used, the foam cotton is required to be placed between a measuring head and a measuring table and then detected, the detection precision is higher, but the detection speed is slower, if the moving EPE foam cotton is continuously detected by adopting the CCD camera, the EPE foam cotton is required to be driven by adopting a conveying belt and a conveying roller, when the conveying roller is contacted with the EPE foam cotton, the conveying roller can generate extrusion force on the surface of the EPE foam cotton, so that the surface of the EPE foam cotton is deformed, and a longer driving belt is required to be arranged until the EPE foam cotton is reset, and then the EPE foam cotton in a normal state can be detected;

Meanwhile, the existing detection equipment is used for detecting EPE foam cotton in a normal state, the compression coefficient of the EPE foam cotton is also an important performance index of the EPE foam cotton, when the EPE foam cotton is detected, the thickness of the EPE foam cotton needs to be measured after being extruded and is matched with the thickness of the EPE foam cotton in the normal state for calculation, and the compression coefficient of the EPE foam cotton can be obtained.

Disclosure of Invention

(One) solving the technical problems

Aiming at the defects of the prior art, the invention provides an EPE foam cotton thickness detection device, which solves the problem that the existing detection equipment is inconvenient to continuously detect the thickness of EPE foam cotton.

(II) technical scheme

The invention aims at achieving the purposes through the following technical scheme that the EPE foam cotton thickness detection device comprises a workbench, wherein a first CCD camera and a second CCD camera are arranged on the front surface of the workbench, and a conveying mechanism is arranged above the workbench and comprises:

The fixing frame is fixedly arranged above the workbench, a transmission belt is connected to the inner wall of the fixing frame in a transmission way, a transmission roller is arranged above the transmission belt, a plurality of limit teeth are arranged on the outer peripheral wall of one end of the transmission roller, the transmission roller and the limit teeth are matched with the transmission belt to move EPE foam cotton, a first CCD camera is arranged on the side surface of the end part of the transmission roller, which is not provided with the limit teeth, the first CCD camera photographs the unextracted EPE foam cotton and detects the thickness, and the transmission belt and the transmission roller are connected with a first driving assembly;

The supporting frame is fixedly arranged above the fixed frame, the moving bars are arranged on the inner wall of the supporting frame in a sliding mode, a plurality of extrusion rollers are arranged between the two moving bars in a rotating mode, an extrusion spring is arranged between the moving bars and the inner top wall of the supporting frame, the extrusion rollers are matched with a transmission belt to carry out self-adaptive extrusion and transmission on EPE foam cotton through the elastic force of the extrusion spring, a second CCD camera is used for photographing and thickness detection on the extruded EPE foam cotton, and the extrusion rollers are connected with a second driving assembly.

Preferably, the first driving assembly comprises a driving motor, the driving motor is fixedly arranged above the workbench, a plurality of rotating shafts are rotationally connected to the inner wall of the fixed frame, the driving end of the driving motor is fixedly connected with one of the rotating shafts, a rotating roller is fixedly sleeved on the peripheral wall of the rotating shaft, the rotating rollers tightly abut against the inner wall of the transmission belt, the end parts of the rotating shafts penetrate through the outer wall of the fixed frame to extend outwards, and a first chain transmission part is connected between the end parts of two adjacent rotating shafts in a transmission manner.

Preferably, the first driving assembly further comprises a plurality of fixing blocks, the fixing blocks are fixedly arranged at the top of the fixing frame, a first transmission shaft is rotatably connected between the two fixing blocks positioned on the front face and the back face, the transmission roller is fixedly sleeved on the peripheral wall of the first transmission shaft, and the end part of the first transmission shaft is in transmission connection with one of the rotation shafts.

Preferably, a second transmission shaft is rotatably connected between the back surface of the fixed frame and the back surface of one of the fixed blocks, the second transmission shaft is fixedly sleeved with two transmission gears which are in meshed connection with the rotating shaft below the second transmission shaft, and a second chain transmission piece is in transmission connection between the first transmission shaft and the second transmission shaft.

Preferably, the second driving assembly comprises a lifting cylinder, the bottom of the lifting cylinder is fixedly connected with a supporting bar, the end parts of the supporting bars are fixedly connected to the top of the supporting frame, guide rods are arranged above the two moving bars, the top ends of the two guide rods penetrate through the top of the supporting frame to extend upwards and are fixedly connected with connecting bars, and the extrusion springs are movably sleeved on the peripheral walls of the guide rods.

Preferably, the end part of the lifting cylinder extending shaft is connected with an L-shaped strip, and the lower transverse part of the L-shaped strip is attached to the lower part of the connecting strip.

Preferably, the second driving assembly further comprises a transmission motor, the transmission motor is located on the side face of one of the moving strips, a driving shaft is fixedly arranged at the driving end of the transmission motor, rotating rods are fixedly inserted on the inner walls of the plurality of extrusion rollers, and the end portions of the rotating rods penetrate through one of the moving strips to extend outwards.

Preferably, a third chain transmission part is arranged between the end part of the driving shaft and one of the rotating rods and between the two adjacent rotating rods, and a motor seat is fixedly connected between the bottom of the transmission motor and the lower part of the end part of the movable strip.

Preferably, the limiting sliding grooves are formed in the inner walls of the two sides of the supporting frame, the limiting sliding blocks are fixedly mounted at the two ends of the moving strip, and the limiting sliding blocks are attached to the inner walls of the limiting sliding grooves.

The invention discloses an EPE foam cotton thickness detection device, which has the following beneficial effects:

1. This EPE foam cotton thickness detection device, because EPE foam cotton is driven under the effect of a plurality of spacing teeth, a plurality of spacing teeth are just installed to transmission roller only one end periphery wall simultaneously, then one side of EPE foam cotton can be slightly extrudeed the transmission by a plurality of spacing teeth downwards, and the opposite side of EPE foam cotton does not receive the extrusion of spacing tooth then can not take place deformation, simultaneously first CCD camera sets up in the side of the transmission roller tip that does not set up spacing tooth, and then makes first CCD camera can take a picture in succession and carry out continuous thickness detection to not extruded EPE foam cotton.

2. This EPE foam cotton thickness detection device makes a plurality of extrusion rollers and EPE foam cotton contact under extrusion spring's effect to extrude EPE foam cotton between a plurality of extrusion rollers and drive belt, then need not to adjust the interval of a plurality of extrusion rollers and drive belt, utilize extrusion spring's elasticity can carry out self-adaptation extrusion according to EPE foam cotton, second drive assembly drives a plurality of extrusion rollers simultaneously and rotates, then driven EPE foam cotton and outwards transmitted when being extruded, and then make the second CCD camera can take a picture and carry out continuous thickness detection to the EPE foam cotton after fully extruding in succession, reach more effective continuous detection effect.

3. This EPE foam cotton thickness detection device, when lifting cylinder during operation, drive the L type strip of its extension axle tip and carry out vertical movement, and the below horizontal part of L type strip is laminated mutually with the below of connecting rod, then can pull the connecting rod and upwards remove when L type strip upwards remove, and pull the removal strip through the guide bar and upwards remove, and then make a plurality of extrusion rollers upwards remove, and compressed extrusion spring, when lifting cylinder drives L type strip and resets downwards, L type strip no longer extrudees the connecting rod, make the connecting rod rebound under extrusion spring's effect and reset, make a plurality of extrusion rollers downwards remove and extrude EPE foam cotton through extrusion spring.

Drawings

In order to more clearly illustrate the embodiments of the invention or the technical solutions in the prior art, the drawings that are required in the embodiments or the description of the prior art will be briefly described, it being obvious that the drawings in the following description are only some embodiments of the invention, and that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

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

FIG. 2 is a schematic view of the back structure of the present invention;

FIG. 3 is a schematic view of the rear portion structure of the present invention;

FIG. 4 is a schematic view of the structure of the transmission roller, the rotating roller and the like of the invention;

FIG. 5 is a schematic view of the structure of the drive roller and spacing teeth of the present invention;

FIG. 6 is a schematic view of the structure of the support frame, the squeeze roller and the second drive assembly of the present invention;

FIG. 7 is a schematic view of a lifting cylinder and the like according to the present invention;

FIG. 8 is a schematic view of the structure of the support frame and the squeeze roller of the present invention;

fig. 9 is a schematic view of a portion of a second driving assembly according to the present invention.

In the figure, 1, a workbench; 101, a first CCD camera, 102, a second CCD camera, 2, a fixed frame, 201, a driving belt, 202, a driving roller, 203, a limit tooth, 3, a supporting frame, 301, a moving bar, 302, a squeezing roller, 303, a squeezing spring, 4, a driving motor, 401, a rotating shaft, 402, a rotating roller, 403, a first chain transmission piece, 404, a fixed block, 405, a first transmission shaft, 406, a second transmission shaft, 407, a driving gear, 408, a second chain transmission piece, 5, a lifting cylinder, 501, a supporting bar, 502, a connecting bar, 503, a guide bar, 504, an L-shaped bar, 6, a driving motor, 601, a driving shaft, 602, a rotating bar, 603, a third chain transmission piece, 604, a motor cabinet, 605, a limit chute, 606 and a limit slider.

Detailed Description

For the purpose of making the objects, technical solutions and advantages of the embodiments of the present invention more clear, the technical solutions in the embodiments of the present invention are clearly and completely described, and it is obvious that the described embodiments are 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.

The embodiment of the application solves the problem that the existing detection equipment is inconvenient to continuously detect the thickness of EPE foam cotton by providing the EPE foam cotton thickness detection device. The first CCD camera 101 can continuously photograph and detect the continuous thickness of the unextracted EPE foam cotton, and the second CCD camera 102 can continuously photograph and detect the continuous thickness of the fully-extruded EPE foam cotton, so that a more effective continuous detection effect is achieved.

In order to better understand the above technical solutions, the following detailed description will refer to the accompanying drawings and specific embodiments.

The embodiment of the invention discloses an EPE foam cotton thickness detection device.

According to the drawings 1-9, the device comprises a workbench 1, a first CCD camera 101 and a second CCD camera 102 are arranged on the front surface of the workbench 1, and a conveying mechanism is arranged above the workbench 1, wherein the conveying mechanism comprises:

The fixed frame 2 is fixedly arranged above the workbench 1, a transmission belt 201 is connected to the inner wall of the fixed frame 2 in a transmission way, a transmission roller 202 is arranged above the transmission belt 201, a plurality of limiting teeth 203 are arranged on the outer peripheral wall of one end of the transmission roller 202, the transmission roller 202 and the limiting teeth 203 are matched with the transmission belt 201 to move EPE foam cotton, a first CCD camera 101 is arranged on the side surface of the end part of the transmission roller 202 where the limiting teeth 203 are not arranged, the first CCD camera 101 photographs the unextruded EPE foam cotton and detects the thickness, and the transmission belt 201 and the transmission roller 202 are connected with a first driving assembly;

The supporting frame 3 is fixedly arranged above the fixed frame 2, the moving strips 301 are slidably arranged on the inner wall of the supporting frame 3, a plurality of extrusion rollers 302 are rotatably arranged between the two moving strips 301, extrusion springs 303 are arranged between the moving strips 301 and the inner top wall of the supporting frame 3, the plurality of extrusion rollers 302 are matched with the transmission belt 201 to adaptively extrude and transmit EPE foam cotton by utilizing the elasticity of the extrusion springs 303, the second CCD camera 102 photographs and detects the thickness of the extruded EPE foam cotton, and the plurality of extrusion rollers 302 are connected with a second driving assembly.

The CCDs in the first and second CCD cameras 101 and 102 are semiconductor devices, which can convert optical images into digital signals, and further convert captured image signals into digital signals, so as to achieve the function of thickness detection, which is a mature technology in the prior art, and therefore is not described in detail in the embodiments of the present invention.

In the use process, first drive assembly is utilized to drive the driving belt 201 to drive on the inner wall of the fixed frame 2, meanwhile, the driving roller 202 above the driving belt 201 is enabled to rotate, the end part of the EPE foam cotton is inserted between the driving belt 201 and the driving roller 202, the plurality of limiting teeth 203 on the outer side of the driving roller 202 are enabled to be in contact with the EPE foam cotton, the plurality of limiting teeth 203 are slightly inserted above the EPE foam cotton, then the EPE foam cotton is pushed to continue to move until the EPE foam cotton enters the lower part of the other driving roller 202, at the moment, the first CCD camera 101 between the two driving rollers 202 is used for photographing the EPE foam cotton, because the EPE foam cotton is driven under the action of the plurality of limiting teeth 203, and meanwhile, only one end peripheral wall of the driving roller 202 is provided with the plurality of limiting teeth 203, one side of the EPE foam cotton is enabled to be slightly and downwards extruded and transmitted, the other side of the EPE foam cotton is not extruded by the limiting teeth 203, meanwhile, the first CCD camera 101 is arranged on the side of the EPE foam cotton, the first CCD camera is enabled to be not required to be continuously checked for photographing, and the first CCD camera is required to be continuously checked for photographing the EPE foam cotton, and the thickness is required to be continuously checked;

When the end of EPE foam cotton is close to a plurality of extrusion rollers 302, utilize the second drive assembly of setting, drive a plurality of extrusion rollers 302 and upwards move simultaneously, compression spring 303 has been compressed, make EPE foam cotton enter into the below of a plurality of extrusion rollers 302 this moment, when the end of EPE foam cotton shifts out from extrusion roller 302 below, make a plurality of extrusion rollers 302 reset, make a plurality of extrusion rollers 302 and EPE foam cotton contact under the effect of extrusion spring 303, and extrude EPE foam cotton between a plurality of extrusion rollers 302 and drive belt 201, then need not to adjust the interval of a plurality of extrusion rollers 302 and drive belt 201, the elasticity that utilizes extrusion spring 303 can carry out the self-adaptation extrusion according to EPE foam cotton, and the quantity of extrusion spring 303 and extrusion roller 302 can be according to actual free setting, can guarantee that a plurality of extrusion rollers 302 possess sufficient pressure to fully extrude EPE foam cotton, simultaneously, second drive a plurality of extrusion rollers 302 rotate, then drive EPE foam cotton and outwards transmit when being extruded, and then make the continuous detection of second CCD foam cotton can carry out continuous detection for continuous thickness, continuous detection can be more effective continuous detection of EPE foam cotton.

Further, the first driving assembly comprises a driving motor 4, the driving motor 4 is fixedly arranged above the workbench 1, a plurality of rotating shafts 401 are rotatably connected to the inner wall of the fixed frame 2, the driving end of the driving motor 4 is fixedly connected with one of the rotating shafts 401, rotating rollers 402 are fixedly sleeved on the peripheral wall of the rotating shaft 401, the rotating rollers 402 tightly abut against the inner wall of the driving belt 201, the end parts of the rotating shafts 401 penetrate through the outer wall of the fixed frame 2 to extend outwards, and a first chain transmission part 403 is connected between the end parts of the two adjacent rotating shafts 401 in a transmission manner.

When the driving motor 4 works, the driving end drives one of the rotating shafts 401 to rotate, and under the action of the plurality of first chain transmission pieces 403, the plurality of rotating shafts 401 simultaneously rotate, so that the plurality of rotating rollers 402 rotate and drive the transmission belt 201 to carry out cyclic transmission.

Further, the first driving assembly further comprises a plurality of fixing blocks 404, the fixing blocks 404 are fixedly mounted on the top of the fixing frame 2, a first transmission shaft 405 is rotatably connected between the two fixing blocks 404 located on the front face and the back face, the transmission roller 202 is fixedly sleeved on the peripheral wall of the first transmission shaft 405, and the end portion of the first transmission shaft 405 is in transmission connection with one of the rotation shafts 401.

Further, a second transmission shaft 406 is rotatably connected between the back surface of the fixed frame 2 and the back surface of one of the fixed blocks 404, two transmission gears 407 engaged with each other are fixedly sleeved on the second transmission shaft 406 and the rotation shaft 401 below the second transmission shaft 406, and a second chain transmission member 408 is connected between the first transmission shaft 405 and the second transmission shaft 406 in a transmission manner.

By using the two driving gears 407, the second driving shaft 406 can be driven to reversely rotate by the rotating shaft 401 when rotating, and the first driving shaft 405 rotates under the action of the second chain driving member 408, so that the driving roller 202 outside the first driving shaft 405 reversely rotates relative to the rotating roller 402, and the rotating roller 402 and the driving belt 201 can convey EPE foam cotton therebetween.

Specifically disclosed, the second driving assembly comprises a lifting cylinder 5, the bottom of the lifting cylinder 5 is fixedly connected with a supporting bar 501, the end parts of the supporting bars 501 are fixedly connected to the top of the supporting frame 3, guide rods 503 are installed above the two moving bars 301, the top ends of the two guide rods 503 penetrate through the top of the supporting frame 3 to extend upwards and are fixedly connected with connecting bars 502, and the extrusion springs 303 are movably sleeved on the peripheral walls of the guide rods 503.

Specifically disclosed, the end of the lifting cylinder 5 extending out of the shaft is connected with an L-shaped strip 504, and the lower transverse part of the L-shaped strip 504 is attached to the lower part of the connecting strip 502.

When the lifting cylinder 5 works, the L-shaped strip 504 extending out of the end part of the shaft is driven to vertically move, the lower transverse part of the L-shaped strip 504 is attached to the lower part of the connecting strip 502, when the L-shaped strip 504 moves upwards, the connecting strip 502 can be pulled to move upwards, the moving strip 301 is pulled to move upwards through the guide rod 503, the plurality of extrusion rollers 302 move upwards, the extrusion springs 303 are compressed, when the lifting cylinder 5 drives the L-shaped strip 504 to reset downwards, the L-shaped strip 504 does not extrude the connecting strip 502 any more, the connecting strip 502 is enabled to rebound under the action of the extrusion springs 303, and the plurality of extrusion rollers 302 move downwards and extrude EPE foam cotton through the extrusion springs 303.

Specifically disclosed, the second driving assembly further comprises a transmission motor 6, the transmission motor 6 is located at the side face of one of the moving bars 301, a driving shaft 601 is fixedly arranged at the driving end of the transmission motor 6, rotating rods 602 are fixedly inserted on the inner walls of the plurality of extrusion rollers 302, and the end portions of the rotating rods 602 penetrate through one of the moving bars 301 to extend outwards.

Further, a third chain transmission member 603 is installed between the end of the driving shaft 601 and one of the rotating rods 602 and between two adjacent rotating rods 602, and a motor seat 604 is fixedly connected between the bottom of the transmission motor 6 and the lower part of the end of the moving bar 301.

Through the transmission motor 6 that sets up, transmission motor 6 is at the during operation, and its drive shaft 601 utilizes third chain drive piece 603 to drive a plurality of dwells 602 and rotates, and then makes a plurality of extrusion rollers 302 rotate simultaneously, and then can carry the EPE foam cotton of extrusion between a plurality of extrusion rollers 302 and drive belt 201.

The first chain transmission member 403, the second chain transmission member 408 and the third chain transmission member 603 are each composed of two sprockets and a chain, the two sprockets are sleeved outside the corresponding structure, and the chain is transmitted between the two sprockets, so that the two sprockets can rotate simultaneously.

Further, limiting sliding grooves 605 are formed in the inner walls of the two sides of the supporting frame 3, limiting sliding blocks 606 are fixedly mounted at the two ends of the moving strip 301, and the limiting sliding blocks 606 are attached to the inner walls of the limiting sliding grooves 605.

Through the spacing spout 605 and the spacing slider 606 that set up, and then can carry out spacingly to the movable strip 301 for the movable strip 301 can only carry out vertical slip.

The foregoing has shown and described the basic principles and main features of the present invention and the advantages of the present invention. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, and that the above embodiments and descriptions are merely illustrative of the principles of the present invention, and various changes and modifications may be made without departing from the spirit and scope of the invention, which is defined in the appended claims. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims (5)

1. The utility model provides a EPE foam cotton thickness detection device, includes workstation (1), its characterized in that, first CCD camera (101) and second CCD camera (102) are installed to the front of workstation (1), and conveying mechanism is installed to the top of workstation (1), and conveying mechanism includes:

the fixing frame (2) is fixedly arranged above the workbench (1), a transmission belt (201) is connected to the inner wall of the fixing frame (2) in a transmission way, a transmission roller (202) is arranged above the transmission belt (201), a plurality of limiting teeth (203) are arranged on the outer peripheral wall of one end of the transmission roller (202), the transmission roller (202) and the limiting teeth (203) are matched with the transmission belt (201) to move EPE foam cotton, a first CCD camera (101) is arranged on the side face of the end part of the transmission roller (202) where the limiting teeth (203) are not arranged, the first CCD camera (101) photographs the unextruded EPE foam cotton and detects the thickness, and the transmission belt (201) and the transmission roller (202) are connected with a first driving component;

The support frames (3) are symmetrically and fixedly arranged above the fixed frames (2), moving strips (301) are slidably arranged on the inner walls of the two support frames (3), a plurality of extrusion rollers (302) are rotatably arranged between the two moving strips (301), extrusion springs (303) are arranged between the moving strips (301) and the inner top wall of the support frames (3), the extrusion rollers (302) are matched with a transmission belt (201) to adaptively extrude and transmit EPE foam cotton by utilizing the elasticity of the extrusion springs (303), a second CCD camera (102) photographs and detects the thickness of the extruded EPE foam cotton, and the extrusion rollers (302) are connected with a second driving assembly;

The second driving assembly comprises a lifting cylinder (5), the bottom of the lifting cylinder (5) is fixedly connected with a supporting bar (501), the end parts of the supporting bar (501) are fixedly connected to the top of the supporting frame (3), guide rods (503) are arranged above the two moving bars (301), the top ends of the two guide rods (503) penetrate through the top of the supporting frame (3) to extend upwards and are fixedly connected with connecting bars (502), and the extrusion springs (303) are movably sleeved on the outer peripheral walls of the guide rods (503);

An L-shaped strip (504) is connected to the end part of the extension shaft of the lifting cylinder (5), and the lower transverse part of the L-shaped strip (504) is attached to the lower part of the connecting strip (502);

The second driving assembly further comprises a transmission motor (6), the transmission motor (6) is positioned on the side face of one of the moving strips (301), a driving shaft (601) is fixedly arranged at the driving end of the transmission motor (6), rotating rods (602) are fixedly inserted on the inner walls of the plurality of extrusion rollers (302), and the end parts of the rotating rods (602) penetrate through one of the moving strips (301) to extend outwards;

A third chain transmission piece (603) is arranged between the end part of the driving shaft (601) and one of the rotating rods (602) and between two adjacent rotating rods (602), and a motor base (604) is fixedly connected between the bottom of the transmission motor (6) and the lower part of the end part of the moving strip (301).

2. The EPE foam cotton thickness detection device according to claim 1, wherein the first driving assembly comprises a driving motor (4), the driving motor (4) is fixedly installed above the workbench (1), a plurality of rotating shafts (401) are rotatably connected to the inner wall of the fixed frame (2), the driving end of the driving motor (4) is fixedly connected with one of the rotating shafts (401), rotating rollers (402) are fixedly sleeved on the peripheral wall of the rotating shaft (401), the rotating rollers (402) tightly abut against the inner wall of the transmission belt (201), the end parts of the rotating shafts (401) penetrate through the outer wall of the fixed frame (2) to extend outwards, and a first chain transmission part (403) is connected between the end parts of two adjacent rotating shafts (401).

3. The EPE foam cotton thickness detection device according to claim 2, wherein the first driving assembly further comprises a plurality of fixing blocks (404), the fixing blocks (404) are fixedly installed at the top of the fixing frame (2), a first transmission shaft (405) is rotatably connected between the two fixing blocks (404) located on the front face and the back face, the transmission roller (202) is fixedly sleeved on the peripheral wall of the first transmission shaft (405), and the end portion of the first transmission shaft (405) is in transmission connection with one of the rotation shafts (401).

4. An EPE foam thickness detection apparatus according to claim 3, wherein a second transmission shaft (406) is rotatably connected between the back of the fixed frame (2) and the back of one of the fixed blocks (404), the second transmission shaft (406) is fixedly sleeved with two transmission gears (407) which are engaged with each other and connected with a rotation shaft (401) below the second transmission shaft, and a second chain transmission member (408) is in transmission connection between the first transmission shaft (405) and the second transmission shaft (406).

5. The EPE foam cotton thickness detection device according to claim 1, wherein limiting sliding grooves (605) are formed in inner walls of two sides of the supporting frame (3), limiting sliding blocks (606) are fixedly mounted at two ends of the moving strip (301), and the limiting sliding blocks (606) are attached to inner walls of the limiting sliding grooves (605).