CN113859951A - Automatic sheet placing method for irradiation crosslinking material - Google Patents

Abstract

The invention belongs to the technical field of irradiation crosslinking, and particularly relates to an automatic sheet placing method for an irradiation crosslinking material. The invention ensures that the sheet to be irradiated stays for 0.5-40min in the effective irradiation area by arranging the sheet stopper on the irradiation chamber, thereby achieving the purpose of effective irradiation crosslinking. The invention has the following advantages: firstly, single-side irradiation is carried out on a sheet to be irradiated for 0.5-40min, so that the sufficient and proper irradiation amount is ensured, and double-side irradiation is required for the thicker sheet to be irradiated; secondly, the sheet stopper can leave the sheet to be irradiated in an effective irradiation area, the retention time is controllable, and the efficiency and the quality of irradiation crosslinking processing are improved; thirdly, the sheet stopper has simple and reasonable structure and low cost, the establishment and the release of the blocking action are very convenient, the stability of the sheet to be irradiated is high when the sheet to be irradiated is blocked, the sheet to be irradiated is not easy to move away accidentally, and the sheet stopper can be easily output outwards after irradiation is finished.

Description

Automatic sheet placing method for irradiation crosslinking material

Technical Field

The invention belongs to the technical field of irradiation crosslinking, and particularly relates to an automatic sheet placing method for an irradiation crosslinking material.

Background

Irradiation crosslinking refers to a high polymer material modification and enhancement technology, and irradiation of high polymer materials is performed in various ways of rays, electron beams and the like, so that long chains inside the high polymer materials can be crosslinked and combined, the original performance of the high polymer materials is finally improved, or new functions are added, and the most common product in the technology is an irradiation crosslinking foaming polyethylene material.

When the irradiation crosslinking is carried out, raw materials are required to be input below the irradiation crosslinking host machine and kept for a period of time to ensure sufficient irradiation amount, the raw materials are generally in a sheet shape, so the operation is called sheet placing, the automatic sheet placing operation is generally completed by adding a conveying belt through a stepping motor, and the conveying belt is controllably advanced, so that the raw materials can be ensured to be kept below the irradiation crosslinking host machine for sufficient and proper time.

On the other hand, in the existing solution of the stepping motor, the stepping motor is too expensive, so that the practicability is general, and therefore, a simpler, more economical and more effective irradiation crosslinking raw material feeding device is urgently needed to ensure that the time for automatically placing the sheet is appropriate, controllable and adjustable.

The patent publication number is CN207209246U, and the china utility model patent that bulletins day is 2018.04.10 discloses a rail mounted conveying mechanism for irradiation product, including base, transmission platform and control panel, control panel installs in the base left side, the control panel left side is equipped with the display, the display right side is equipped with control button, base exit installation infrared inductor, the base upper end is equipped with left track, middle track and right track, the transmission platform comprises transmission track and the wheel that rolls, the installation pivot in the middle of the wheel that rolls, the pivot left side is equipped with the rotation motor, be equipped with the casing on the transmission track, casing top side is equipped with anti-skidding border, casing bottom installation rolling support, rolling support side-mounting roll ball.

But the rail mounted conveying mechanism in this utility model patent, it is when carrying and treating the irradiation product, lacks the product and stops the function, consequently treats the effective irradiation time of irradiation product in irradiation equipment below, is exactly the through-time, and this has just led to following several problems: firstly, the irradiation quantity of the product is insufficient, and the irradiation modification effect is poor; secondly, the irradiation time of products with different specifications in the same batch is the same, so that the problems of excessive irradiation or insufficient irradiation can occur; thirdly, when the irradiation amount of the products in different batches needs to be adjusted, the whole conveying mechanism needs to be changed, which wastes time and labor and increases the cost.

Disclosure of Invention

The invention provides an automatic sheet placing method for an irradiation crosslinking material, which can ensure that a sheet to be irradiated stays for 0.5-40min in an effective irradiation area by arranging a sheet stopper on an irradiation chamber, thereby achieving the aim of effective irradiation crosslinking.

The technical scheme adopted by the invention for solving the problems is as follows: the automatic sheet placing method for the irradiation crosslinking material is characterized in that the sheet placing residence time of the sheet to be irradiated below an irradiation host machine is adjusted through a sheet stopper, the sheet to be irradiated completely enters an effective irradiation area as an irradiation operation timing starting point, the sheet to be irradiated begins to move out of the effective irradiation area as an irradiation operation timing end point, and the irradiation operation time is 0.5-40 min.

The further preferred technical scheme is as follows: the sheet stopper comprises a timing on-off device, a driving motor unit arranged on the outer side surface of the irradiation chamber and connected with the timing on-off device, a mounting hole unit arranged on a vertical plate of the irradiation chamber, a sliding plate unit arranged on the mounting hole unit and used for receiving inward shifting action of the driving motor unit, and a rotating plate unit which is hinged to the inner end of the sliding plate unit and used for releasing the blocking effect of the sheet to be irradiated in a mode that the sliding plate unit is obliquely jacked up and then upwards on the mounting hole unit.

The further preferred technical scheme is as follows: the driving motor unit comprises a fixing plate, a speed reducing motor and a rotating plate, wherein the fixing plate is arranged on the outer side surface of the irradiation chamber and used for installing the timing on-off device, the speed reducing motor is arranged on the fixing plate and connected with the timing on-off device, and the rotating plate is arranged on the speed reducing motor and used for pushing the outer end of the sliding plate unit chamber inwards.

The further preferred technical scheme is as follows: the mounting hole unit comprises a rectangular hole formed in the vertical plate of the irradiation chamber and an inclined opening formed in the edge below the inner side of the rectangular hole and used for jacking the rotating plate unit upwards.

The further preferred technical scheme is as follows: the sliding plate unit comprises a rectangular plate arranged on the rectangular hole, a limiting plate arranged on the lower surface of the rectangular plate and used for blocking the outer side surface of the irradiation chamber, a fixed orifice plate arranged on the indoor end of the rectangular plate and used for hinging the rotating plate unit, and a hinging bolt arranged on the fixed orifice plate.

The further preferred technical scheme is as follows: the sliding plate unit also comprises a head groove arranged at the outer end of the rectangular plate chamber, and a fixed roller arranged on the head groove and used for receiving the poking action of the rotating plate.

The further preferred technical scheme is as follows: the sliding plate unit further comprises an upper fixing plate arranged on the lower surface of the fixed orifice plate, a downward inclined plate arranged on the upper fixing plate, and a lower limiting plate arranged on the downward inclined plate and used for supporting the rotating plate unit.

The further preferred technical scheme is as follows: the rotating plate unit comprises a rotating hole plate arranged on the hinged bolt, an indoor plate arranged on the rotating hole plate and used for receiving limiting and supporting actions of the limiting plate below, a vertical plate arranged on the indoor plate and used for blocking a sheet to be irradiated, and a roller part arranged on the lower surface of the indoor plate and jacked upwards on the inclined port.

The further preferred technical scheme is as follows: the roller part comprises a mounting plate arranged on the lower surface of the indoor plate, a roller groove arranged on the mounting plate, and a second roller arranged on the roller groove.

The further preferred technical scheme is as follows: the rotating plate unit further comprises balls arranged on the side face and the lower end face of the vertical plate.

The invention has the following advantages: firstly, single-side irradiation is carried out on a sheet to be irradiated for 0.5-40min, so that the sufficient and proper irradiation amount is ensured, and double-side irradiation is required for the thicker sheet to be irradiated; secondly, the sheet stopper can leave the sheet to be irradiated in an effective irradiation area, the retention time is controllable, and the efficiency and the quality of irradiation crosslinking processing are improved; thirdly, the sheet stopper has simple and reasonable structure and low cost, the establishment and the release of the blocking action are very convenient, the stability of the sheet to be irradiated is high when the sheet to be irradiated is blocked, the sheet to be irradiated is not easy to move away accidentally, and the sheet to be irradiated can be easily output outwards after the irradiation is finished; fourthly, the main structure of the whole sheet stopper is positioned outside the irradiation chamber, safety and controllability are achieved, the stopper realizes effective switching between the two states of blocking and unblocking of the sheet to be irradiated through a physical structure, the whole using process is stable, and the service life is long.

Drawings

Fig. 1 is a schematic view of a sheet stopper according to the present invention.

Fig. 2 is a schematic view of a position structure of the driving motor unit according to the present invention.

Fig. 3 is a schematic view showing the position structure of the sliding plate unit according to the present invention.

Fig. 4 is a schematic view illustrating a rotating use of the rotating plate unit according to the present invention.

Fig. 5 is a schematic view of the position structure of the roller unit according to the present invention.

Fig. 6 is a schematic view of the position structure of the ball of the present invention.

In the drawings, the reference numerals denote the following components: the irradiation system comprises an irradiation host a, an irradiation chamber b, a sheet c to be irradiated, a timing switch 11, a driving motor unit 1, a mounting hole unit 2, a sliding plate unit 3, a rotating plate unit 4, a fixing plate 101, a reduction motor 102, a rotating plate 103, a rectangular hole 201, an inclined port 202, a rectangular plate 301, a limiting plate 302, a fixing orifice plate 303, a hinge bolt 304, an end groove 305, a fixing roller 306, an upper fixing plate 307, a downward inclined plate 308, a lower limiting plate 309, a rotating orifice plate 401, an indoor plate 402, a vertical plate 403, a roller portion 404, a mounting plate 404a, a roller groove 404b, a second roller 404c and a ball 405.

Detailed Description

The following description is only a preferred embodiment of the present invention and is not intended to limit the scope of the present invention.

Example (b): as shown in fig. 1-6, in the automatic sheet placing method for irradiation cross-linked material, the sheet placing residence time of the sheet c to be irradiated below the irradiation host a is adjusted by the sheet stopper, the sheet c to be irradiated completely enters the effective irradiation region as the irradiation operation timing starting point, the sheet c to be irradiated begins to move out of the effective irradiation region as the irradiation operation timing ending point, and the irradiation operation time is 0.5-40 min.

In this embodiment, the sheet c to be irradiated includes various polyolefin foam plastics, the type of the irradiation host a includes ultraviolet irradiation crosslinking equipment in the prior art and various ray irradiation crosslinking equipment, the sheet c to be irradiated is an effective irradiation region in the prior art within a certain area below the irradiation host a, and if the sheet c to be irradiated is too thick, double-sided irradiation is necessary, so that the time for single-sided irradiation is preferably controlled to be 0.5 to 40min, even if the time for single-sided irradiation is further prolonged for the sheet c to be irradiated with a very large thickness, the increase of the crosslinking degree is not obvious, the yield is not high, and therefore the single-sided irradiation time of 0.5 to 40min is determined.

The sheet stopper comprises a timing on-off device 11, a driving motor unit 1 arranged on the outer side surface of an irradiation chamber b and connected with the timing on-off device 11, a mounting hole unit 2 arranged on a vertical plate of the irradiation chamber b, a sliding plate unit 3 arranged on the mounting hole unit 2 and used for receiving inward shifting action of the driving motor unit 1, and a rotating plate unit 4 which is hinged to the indoor end of the sliding plate unit 3 and used for releasing blocking action of a sheet c to be irradiated in a mode that the mounting hole unit 2 is obliquely jacked up and then upwards.

In this embodiment, the conveyer belt below the sheet c to be irradiated is equipped with a simple and inexpensive ordinary motor to ensure that the conveyer belt moves relatively slowly all the time, and the timing on-off device 11 is a "smart socket", "microcomputer switch" or "timing switch" commonly used in the prior art to ensure that the on-off time of the circuit on the driving motor unit 1 is controllable.

Further, the specific manner in which the sheet c to be irradiated stays on the conveyor belt to be subjected to irradiation crosslinking is: the sheet c to be irradiated is moved to the rotating plate unit 4 by the conveyor belt, at this time, the rotating plate unit 4 is not tilted yet, the sliding plate unit 3 is always shifted by the driving motor unit 1 to be pressed on the outer side surface of the irradiation chamber b, and thus the sliding plate unit 3 and the rotating plate unit 4 are integrally immobile, so that the sheet c to be irradiated can be continuously blocked, and the irradiation crosslinking effect of sufficient time is ensured.

Finally, according to the characteristics of the sheet c to be irradiated and the specific parameters of the irradiation host a, the predetermined passage time countdown of the timing switch 11 is finished, and then the driving motor unit 1 stops shifting the sliding plate unit 3 inwards, and then the sliding plate unit 3 and the rotating plate unit 4 are pushed by the sheet c to be irradiated as a whole and pushed forwards until the rotating plate unit 4 abuts against the inclined surface of the mounting hole unit 2, so that the rotating plate unit 4 rotates upwards to open a forward opening for the sheet c to be irradiated, and finally the sheet c to be irradiated is wiped out at the lower end of the rotating plate unit 4, and the whole irradiation crosslinking operation is effectively finished.

In this process, the following points need to be noted: firstly, the static friction force between the conveying belt and the sheet c to be irradiated needs to be relatively large; secondly, the lower end of the rotating plate unit 4 is arranged to be relatively smooth, so that the sheet c to be irradiated which is going out is prevented from being stuck.

The driving motor unit 1 includes a fixing plate 101 disposed on an outer side surface of the irradiation chamber b and for mounting the timing switch 11, a reduction motor 102 disposed on the fixing plate 101 and connected to the timing switch 11, and a rotation plate 103 disposed on the reduction motor 102 and for pushing an outdoor end of the sliding plate unit 3 inward.

In this embodiment, the rotating plate 103 is made of conventional medium elastic rubber, so as to ensure that the sliding plate unit 3 can be properly bent and passed through the outdoor end thereof, thereby avoiding the rigid locking problem between the two.

The mounting hole unit 2 comprises a rectangular hole 201 arranged on the vertical plate of the irradiation chamber b and an inclined opening 202 arranged on the edge below the inner side of the rectangular hole 201 and used for jacking up the rotating plate unit 4.

In this embodiment, the length and width of the rectangular hole 201 are 0.2-0.5cm larger than the length and width of the sliding plate unit 3, so as to prevent the sliding plate unit 3 from being displaced in a harmful manner, and ensure that the sliding plate unit 3 can only slide horizontally, while the inclined surface of the inclined opening 202 is a force application part where the rotating plate unit 4 is forced to rotate upward, and the rotating plate unit 4 does not touch the inner wall of the rectangular hole 201 when rotating upward.

The sliding plate unit 3 includes a rectangular plate 301 disposed on the rectangular hole 201, a stopper plate 302 disposed on a lower surface of the rectangular plate 301 for stopping on an outer side surface of the irradiation chamber b, a fixed orifice plate 303 disposed on an inner end of the rectangular plate 301 for hinging the rotating plate unit 4, and a hinge bolt 304 disposed on the fixed orifice plate 303.

In this embodiment, when the rotating plate unit 4 blocks the sheet c to be irradiated, the main body is kept horizontal, the rectangular plate 301 is completely inserted into the rectangular hole 201, when the rotating plate unit 4 rotates upward, the sheet c to be irradiated is already subjected to the last discharging operation, the rectangular plate 301 is partially inserted into the rectangular hole 201, and the remaining length of the rectangular hole 201 is reserved for the hinge joint between the fixed orifice plate 303 and the rotating plate unit 4, so that the rotating plate unit 4 has a space for rotating upward.

In addition, the rotating plate 103 shifts the rectangular plate 301 at a relatively fast speed, and the sheet c to be irradiated is also actually jacked up the rotating plate unit 4, so that the whole sliding plate unit 3, the rotating plate unit 4 and the sheet c to be irradiated are in a state of frequent small left-right vibration, but the normal irradiation crosslinking operation of the sheet c to be irradiated is not affected, and the limiting plate 302 also frequently impacts the outer side surface of the irradiation chamber b in the process, and certainly, the situation is not hindered.

The sliding plate unit 3 further includes a head slot 305 disposed at an outer end of the rectangular plate 301, and a fixed roller 306 disposed at the head slot 305 and configured to receive a toggle motion of the rotating plate 103.

In this embodiment, the fixed roller 306 is used to reduce the abrasion rate of both the rotating plate 103 and the rectangular plate 301 by improving the sliding friction and the hard squeezing deformation between the rotating plate 103 and the end surface of the rectangular plate 301 to rolling friction.

The sliding plate unit 3 further includes an upper fixed plate 307 provided on a lower surface of the fixed orifice plate 303, a downwardly inclined plate 308 provided on the upper fixed plate 307, and a lower limit plate 309 provided on the downwardly inclined plate 308 for supporting the rotating plate unit 4.

In this embodiment, the hinge bolt 304 cannot clamp and fix the fixed orifice plate 303 and the rotating plate unit 4, and the rotating plate unit 4 can be easily rotated, and the upper fixed plate 307, the downward inclined plate 308 and the lower limit plate 309 form a "Z" structure, which ensures that the rotating plate unit 4 can only rotate upward and cannot rotate downward.

The rotating plate unit 4 includes a rotating orifice plate 401 provided on the hinge bolt 304, an indoor plate 402 provided on the rotating orifice plate 401 and adapted to receive the restricting support action of the lower restricting plate 309, a vertical plate 403 provided on the indoor plate 402 and adapted to block the sheet c to be irradiated, and a roller portion 404 provided on a lower surface of the indoor plate 402 and urged upward on the inclined port 202.

In this embodiment, the whole rotating plate unit 4 is located in the irradiation chamber b, so that the rotating plate unit 4 may be made of an inorganic non-metallic material, such as glass, which has no influence on irradiation cross-linking, wherein the vertical plate 403 is used to directly contact and block the sheet c to be irradiated, and the distance between the lower end surface of the vertical plate 403 and the conveyor belt is ensured to be smaller than the thickness of the sheet c to be irradiated.

The roller part 404 includes a mounting plate 404a disposed on a lower surface of the indoor plate 402, a roller groove 404b disposed on the mounting plate 404a, and a second roller 404c disposed on the roller groove 404 b.

In this embodiment, the second roller 404c rolls upward on the inclined opening 202, that is, the entire rotating plate unit 4 can be lifted upward, at this time, the lower end surface of the vertical plate 403 can pass over the sheet c to be irradiated, and the sheet c to be irradiated can be discharged after irradiation crosslinking is completed.

In addition, the thickness of the multiple batches of the sheets c to be irradiated may be different, so that the vertical plate 403 may sufficiently open and give way to the sheets c to be irradiated after the second roller 404c rolls upwards on the inclined port 202 in the following adjusting manner:

first, adjusting the lateral distance between the second roller 404c and the inclined opening 202; secondly, adjusting the inclination angle of the inclined surface of the inclined port 202; third, the diameter of the second roller 404c is adjusted.

The rotating plate unit 4 further includes balls 405 provided on the side and lower end surfaces of the vertical plate 403.

In the present embodiment, the action state of the last discharge of the sheet c to be irradiated is: the side surface of the front end of the sheet c to be irradiated in the moving direction is scribed on the side surface of the vertical plate 403, and the upper surface of the sheet c to be irradiated is scribed on the lower end surface of the vertical plate 403, so that the side surface and the lower end surface of the vertical plate 403 contacting the sheet c need to be ensured to have higher smoothness, and the sheet c to be irradiated is prevented from being stuck, otherwise the sheet c to be irradiated cannot move forwards and is discharged, which is the effect of the two groups of balls 405 on the side surface and the lower end surface.

The embodiments of the present invention have been described in detail with reference to the accompanying drawings, but the present invention is not limited to the above embodiments, and various modifications can be made within the knowledge of those skilled in the art without departing from the gist of the present invention. These are non-inventive modifications, which are intended to be protected by patent laws within the scope of the claims appended hereto.

Claims (10)

1. An automatic sheet placing method for irradiation crosslinking materials is characterized in that: the sheet placing residence time of the sheet (c) to be irradiated below the irradiation host (a) is adjusted through a sheet stopper, the sheet (c) to be irradiated completely enters an effective irradiation area as an irradiation operation timing starting point, the sheet (c) to be irradiated begins to move out of the effective irradiation area as an irradiation operation timing end point, and the irradiation operation time is 0.5-40 min.

2. The automatic sheet placing method for the irradiation crosslinking material according to claim 1, characterized in that: the sheet stopper comprises a timing on-off device (11), a driving motor unit (1) arranged on the outer side surface of an irradiation chamber (b) and connected with the timing on-off device (11), a mounting hole unit (2) arranged on a vertical plate of the irradiation chamber (b), a sliding plate unit (3) arranged on the mounting hole unit (2) and used for receiving inward shifting action of the driving motor unit (1), and a rotating plate unit (4) which is hinged to the inner end of the sliding plate unit (3) and used for releasing blocking action of a sheet (c) to be irradiated in a mode that the mounting hole unit (2) is obliquely jacked up and then upwards.

3. The automatic sheet placing method for the irradiation crosslinking material according to claim 2, characterized in that: the driving motor unit (1) comprises a fixing plate (101) which is arranged on the outer side surface of the irradiation chamber (b) and used for installing the timing on-off device (11), a speed reducing motor (102) which is arranged on the fixing plate (101) and connected with the timing on-off device (11), and a rotating plate (103) which is arranged on the speed reducing motor (102) and used for pushing the outdoor end of the sliding plate unit (3) inwards.

4. The automatic sheet placing method for the irradiation crosslinking material according to claim 3, characterized in that: the mounting hole unit (2) comprises a rectangular hole (201) formed in a vertical plate of the irradiation chamber (b), and an inclined opening (202) formed in a lower edge of the inner side of the rectangular hole (201) and used for jacking the rotating plate unit (4) upwards.

5. The automatic sheet placing method for the irradiation crosslinking material according to claim 4, characterized in that: the sliding plate unit (3) comprises a rectangular plate (301) arranged on the rectangular hole (201), a limiting plate (302) arranged on the lower surface of the rectangular plate (301) and used for blocking on the outer side surface of the irradiation chamber (b), a fixed orifice plate (303) arranged on the indoor end of the rectangular plate (301) and used for hinging the rotating plate unit (4), and a hinging bolt (304) arranged on the fixed orifice plate (303).

6. The automatic sheet placing method for the irradiation crosslinking material according to claim 5, characterized in that: the sliding plate unit (3) further comprises a head groove (305) arranged at the outdoor end of the rectangular plate (301), and a fixed roller (306) arranged on the head groove (305) and used for receiving the toggle action of the rotating plate (103).

7. The automatic sheet placing method for the irradiation crosslinking material according to claim 5, characterized in that: the sliding plate unit (3) further includes an upper fixed plate (307) provided on a lower surface of the fixed orifice plate (303), a downward inclined plate (308) provided on the upper fixed plate (307), and a lower limit plate (309) provided on the downward inclined plate (308) and supporting the rotating plate unit (4).

8. The automatic sheet placing method for the irradiation crosslinking material according to claim 7, characterized in that: the rotating plate unit (4) comprises a rotating hole plate (401) arranged on the hinge bolt (304), an indoor plate (402) arranged on the rotating hole plate (401) and used for receiving limiting and supporting actions of the lower limiting plate (309), a vertical plate (403) arranged on the indoor plate (402) and used for blocking a sheet (c) to be irradiated, and a roller part (404) arranged on the lower surface of the indoor plate (402) and jacked upwards on the inclined port (202).

9. The automatic sheet placing method for the irradiation crosslinking material according to claim 8, characterized in that: the roller part (404) includes an installation plate (404 a) provided on a lower surface of the indoor plate (402), a roller groove (404 b) provided on the installation plate (404 a), and a second roller (404 c) provided on the roller groove (404 b).

10. The automatic sheet placing method for the irradiation crosslinking material according to claim 8, characterized in that: the rotating plate unit (4) further comprises balls (405) disposed on the side and lower end faces of the vertical plate (403).

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