CN216694909U - Thickness monitoring device is used in stone paper production - Google Patents

Abstract

The utility model belongs to the technical field of stone paper production, and particularly relates to a thickness monitoring device for stone paper production. This thickness monitoring device is used in stone paper production, when the rotation axis through setting up calibrator body both sides drives fixed plate synchronous operation, it all moves to relative outside direction to set up two rotation axes, utilize and push away roller surface and friction block friction production static within a definite time, make the roller that pushes away that has the static charge attract the surface of stone paper, and all promote to the outside along with the roller that pushes away of calibrator body both sides, make the stone paper of calibrator body below be stretched out under the attraction of roller that pushes away, avoid stone paper to take place crooked influence to detect, thereby be convenient for improve the accuracy of calibrator testing result.

Description

Thickness monitoring device is used in stone paper production

Technical Field

The utility model relates to the technical field of stone paper production, in particular to a thickness monitoring device for stone paper production.

Background

The stone paper is a novel material between paper and plastic, can replace the traditional partial functional paper and professional paper, and can also replace the traditional most plastic packing materials. The method has the characteristics of low cost and controllable degradation, can save a large amount of cost for users, and does not produce pollution;

the existing stone paper needs to be detected by a non-contact thickness gauge in the production process, the non-contact thickness gauge is used for measuring a measuring instrument and a measured object in a non-contact manner as the name implies, and the measured object can be well protected. The thickness of the stone paper is continuously measured in industrial production, so that the thickness of the stone paper is kept to reach the standard, and inferior products are avoided;

but current stone paper is at production line operation in-process, because stone paper is by the tensile overlength of each production mechanism for stone paper of calibrator below takes place sunken under the effect of self gravity easily, and then makes stone paper's surface take place to buckle, and the calibrator can lead to the existence error when measuring to the stone paper of buckle, influences the testing result of calibrator, thereby influences normal use.

SUMMERY OF THE UTILITY MODEL

The utility model provides a thickness monitoring device for stone paper production based on the technical problem that existing stone paper is easy to bend below a thickness gauge.

The thickness monitoring device for stone paper production comprises a thickness gauge body, wherein a carding device is mounted on the surface of the side wall of the thickness gauge body, the carding device comprises a push roller, and the carding device combs and straightens stone paper through the push roller; the surface of the push roller is contacted with a movable plate, the inner side end of the movable plate is fixedly connected with a thrust spring, the other end of the thrust spring is fixedly provided with a fixed plate, and the surface of the inner side end of the fixed plate is fixedly connected with a rotating shaft; the thickness gauge body is characterized in that the surfaces of two sides of the thickness gauge body are fixedly connected with driving motors, gear boxes are arranged on the surfaces of output shafts of the driving motors, the output shafts of the driving motors and one ends of rotating shafts are driven through the gear boxes, the right-angle gear boxes are used for driving the driving motors and the rotating shafts, so that power is conveniently provided for the rotation of the rotating shafts, and the two driving motors are programmed through an external controller, so that the two driving motors run synchronously; the equal fixedly connected with clutch blocks of both sides wall of calibrator body, the lateral wall of clutch block and the surperficial sliding connection who pushes away the roller utilize the clutch block to be sunken form and lay down the lint with the one side that pushes away roller surface contact to be convenient for push away the roller and produce static when the surface friction of clutch block.

Preferably, the rotating groove has been seted up to the outside end of fly leaf, pushes away the roller and is located the rotating groove, pushes away the both ends of roller and all rotates with the inner wall of rotating groove to be connected.

Through above-mentioned technical scheme, because the push roller is made by the chemical fibre material, the fly leaf is made by insulating plastics material for the surface of push roller when using, all rubs with fly leaf and stone paper and produces static, and then the surface of the push roller of being convenient for carries out the accumulation of static charge.

Preferably, the slot has been seted up to the outside end of fixed plate, and thrust spring is located the inside of slot, and the inboard terminal surface of fly leaf and the inner wall sliding connection of slot.

Through the technical scheme, the movable plate is inserted into the fixed plate, so that the extending length of the movable plate on the surface of the fixed plate can be conveniently controlled.

Preferably, the four fixing plates are distributed in an annular array by taking the axis of the rotating shaft as an array center, and the two ends of the rotating shaft are rotatably connected with the mounting rods.

Through above-mentioned technical scheme, four fixed plates all connect through the rotation axis to be convenient for drive four fixed plates and rotate.

Preferably, one end of each of the two mounting rods is fixedly connected with the surface of the thickness gauge body.

The beneficial effects of the utility model are as follows:

when the rotation axis through setting up calibrator body both sides drives fixed plate synchronous operation, set up two rotation axes and all move to relative outside direction, utilize and push away roller surface and friction block friction production static within a definite time, make the roller that pushes away that has the static charge attract the surface of stone paper, and all promote to the outside along with the roller that pushes away of calibrator body both sides, make the stone paper of calibrator body below be stretched straight under the attraction of roller that pushes away, avoid stone paper to take place crooked influence to detect, thereby be convenient for improve the accuracy of calibrator testing result.

Drawings

Fig. 1 is a schematic diagram of a thickness monitoring device for stone paper production according to the present invention;

FIG. 2 is a perspective view of a movable plate structure of the thickness monitoring device for stone paper production, which is provided by the utility model;

FIG. 3 is a structural cross-sectional view of a fixing plate of the thickness monitoring device for stone paper production, which is provided by the utility model;

fig. 4 is a perspective view of a friction block structure of the thickness monitoring device for stone paper production according to the present invention.

In the figure: 1. a thickness gauge body; 2. pushing the roller; 21. a movable plate; 22. a thrust spring; 23. a fixing plate; 24. a rotating shaft; 25. a rotating tank; 26. a slot; 27. mounting a rod; 3. a motor; 4. a gear case; 5. a friction block.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments.

Referring to fig. 1-4, the thickness monitoring device for stone paper production comprises a thickness gauge body 1, wherein a carding device is mounted on the surface of the side wall of the thickness gauge body 1, the carding device comprises a push roller 2, and the carding device combs and straightens stone paper through the push roller 2; a movable plate 21 is contacted with the surface of the push roller 2, a thrust spring 22 is fixedly connected to the inner side end of the movable plate 21, a fixed plate 23 is fixed to the other end of the thrust spring 22, and a rotating shaft 24 is fixedly connected to the surface of the inner side end of the fixed plate 23; the thickness gauge body 1 is characterized in that the surfaces of two sides of the thickness gauge body 1 are fixedly connected with driving motors 3, gear boxes 4 are arranged on the surfaces of output shafts of the driving motors 3, the output shafts of the driving motors 3 and one ends of rotating shafts 24 are driven through the gear boxes 4, the right-angle gear boxes 4 are used for driving the driving motors 3 and the rotating shafts 24, so that power is conveniently provided for the rotation of the rotating shafts 24, and the two driving motors 3 are programmed through an external controller, so that the two driving motors 3 run synchronously; the equal fixedly connected with clutch blocks 5 of both sides wall of calibrator body 1, the lateral wall of clutch blocks 5 and the surperficial sliding connection of push roller 2 utilize one side that clutch blocks 5 and push roller 2 surface contact to be sunken form and lay and prevent the cotton flannel to be convenient for push roller 2 produces static when the surperficial friction of clutch blocks 5.

Further, a rotating groove 25 is formed in the outer side end of the movable plate 21, the push roller 2 is located in the rotating groove 25, two ends of the push roller 2 are rotatably connected with the inner wall of the rotating groove 25, the push roller 2 is made of chemical fiber materials, and the movable plate 21 is made of insulating plastic materials, so that the surface of the push roller 2 is rubbed with the movable plate 21 and stone paper to generate static electricity when the surface of the push roller 2 is used, and static electricity is accumulated on the surface of the push roller 2 conveniently.

Furthermore, a slot 26 is formed at an outer end of the fixed plate 23, the thrust spring 22 is located inside the slot 26, an inner end surface of the movable plate 21 is slidably connected with an inner wall of the slot 26, and the movable plate is inserted into the fixed plate, so that the extension length of the movable plate on the surface of the fixed plate can be conveniently controlled.

Further, four the fixed plate 23 uses the axis of rotation axis 24 to be the distribution of annular array as the array center, the both ends of rotation axis 24 are all rotated and are connected with installation pole 27, and four fixed plates are all connected through the rotation axis to be convenient for drive four fixed plates and rotate.

Further, one end of each of the two mounting rods 27 is fixedly connected with the surface of the thickness gauge body 1.

When the rotation axis 24 through setting up thickness gauge body 1 both sides drives fixed plate 23 synchronous operation, set up two rotation axis 24 and all move to relative outside direction, utilize and push away 2 surfaces of roller and 5 friction generation static within a definite time of clutch blocks, make the roller that pushes away 2 that have the static charge attract the surface of stone paper, and along with the roller that pushes away 2 of 1 both sides of thickness gauge body all promote to the outside, make the stone paper of thickness gauge body 1 below be stretched straight under the attraction of roller that pushes away 2, avoid stone paper to take place crooked influence testing result, thereby be convenient for improve the characteristics of thickness gauge testing result accuracy.

The working principle is as follows:

when the thickness gauge is used, the thickness gauge body 1 is installed in a stone paper production line, stone paper runs below a measuring end of the thickness gauge body 1, the driving motor 3 is started before the stone paper passes through the thickness gauge body 1, the driving motor 3 drives the rotating shaft 24 to rotate through the gear box 4, the rotating shaft 24 drives the movable plate 21 to rotate through the fixing plate 23, the movable plate 21 drives the push roller 2 to rub at a concave part on the surface of the friction block 5, static charges are carried on the surface of the push roller 2 through frequent rubbing, the driving motor 3 is closed, the stone paper runs and passes below the thickness gauge body 1, and the thickness gauge body 1 and the driving motor 3 are started;

when driving motor 3 drives rotation axis 24 and carries out the pivoted, the surface contact of push roller 2 and stone paper of rotation axis 24 below, and attract stone paper through static, and rotation axis 24 direction of rotation along with thickness gauge body 1 both sides is opposite, make the both ends of stone paper be stretched and straighten by the push roller 2 of thickness gauge body 1 both sides, and along with stone paper and the attraction between push roller 2, make push roller 2 when keeping away from stone paper, outwards tensile fly leaf 21 in from slot 26 through push roller 2, and make thrust spring 22 tensile, and then keep the attraction to stone paper as far as possible, rethread thickness gauge body 1 measures the stone paper after straightening, thereby reachs comparatively accurate stone paper thickness data.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be considered to be within the technical scope of the present invention, and equivalent alternatives or modifications according to the technical solution of the present invention and the inventive concept thereof should be covered by the scope of the present invention.

Claims (5)

1. The utility model provides a thickness monitoring device is used in stone paper production, includes calibrator body (1), its characterized in that: the carding device is arranged on the surface of the side wall of the thickness gauge body (1) and comprises a push roller (2), and the carding device is used for carding and straightening stone paper through the push roller (2);

the surface of the push roller (2) is in contact with a movable plate (21), the inner side end of the movable plate (21) is fixedly connected with a thrust spring (22), the other end of the thrust spring (22) is fixedly connected with a fixed plate (23), and the inner side end surface of the fixed plate (23) is fixedly connected with a rotating shaft (24);

the thickness gauge comprises a thickness gauge body (1), wherein driving motors (3) are fixedly connected to the surfaces of two sides of the thickness gauge body (1), gear boxes (4) are mounted on the surfaces of output shafts of the driving motors (3), and the output shafts of the driving motors (3) and one ends of rotating shafts (24) are driven through the gear boxes (4);

the thickness gauge is characterized in that two side walls of the thickness gauge body (1) are fixedly connected with friction blocks (5), and the side walls of the friction blocks (5) are in sliding connection with the surface of the push roller (2).

2. The thickness monitoring device for stone paper production as claimed in claim 1, wherein: the outer side end of the movable plate (21) is provided with a rotating groove (25), the push roller (2) is located in the rotating groove (25), and the two ends of the push roller (2) are rotatably connected with the inner wall of the rotating groove (25).

3. The thickness monitoring device for stone paper production as claimed in claim 2, wherein: the outer side end of the fixed plate (23) is provided with a slot (26), the thrust spring (22) is located inside the slot (26), and the end surface of the inner side of the movable plate (21) is connected with the inner wall of the slot (26) in a sliding mode.

4. The thickness monitoring device for stone paper production as claimed in claim 3, wherein: the four fixing plates (23) are distributed in an annular array mode by taking the axis of the rotating shaft (24) as the array center, and the two ends of the rotating shaft (24) are connected with mounting rods (27) in a rotating mode.

5. The thickness monitoring device for stone paper production as claimed in claim 4, wherein: one end of each of the two mounting rods (27) is fixedly connected with the surface of the thickness gauge body (1).

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