CN112606523A - Efficient cooling mechanism for producing glass cloth laminated board - Google Patents

Abstract

The invention discloses an efficient cooling mechanism for producing a glass cloth laminated board, which comprises two supporting plates, wherein the bottom ends of the supporting plates are fixedly connected with supporting columns, and the top ends of the supporting plates are provided with cover bodies. According to the invention, the first rotating rod can drive the first gear to rotate through the work of the servo motor, so that the second gear in meshed connection with the bottom end of the first gear can drive the conveyor belt to rotate, the third gear in meshed connection with the top end of the second gear can drive the second rotating rod to move through the rotation of the second gear, the plate can be conveniently placed on the surface of the peak-shaped plate, the plate can be conveniently cooled through the fan in the process of conveying the plate through the rotation of the peak-shaped plate, the subsequent cooling efficiency of the plate can be improved, the first T-shaped rod and the peak-shaped plate are extruded through the first reset spring, the peak-shaped plate can be conveniently contacted with the plate, the friction force between the plate and the plate is increased, and the plate can be conveniently conveyed.

Description

Efficient cooling mechanism for producing glass cloth laminated board

Technical Field

The invention belongs to the technical field of plates, and particularly relates to an efficient cooling mechanism for producing a glass cloth laminated plate.

Background

The plate is a standard-sized flat rectangular building material plate, is applied to the building industry, is used as a component of a wall, a ceiling or a floor, is also a metal plate formed by forging, rolling or casting, and is divided into a thin plate, a middle plate, a thick plate and an extra-thick plate which are usually made into standard-sized flat rectangular building material plates.

It all collects the whole panel of its high-efficient cooling body of production glass cloth laminated board and puts together then putting into cooling body with it and cool off, leads to its cooling efficiency low like this and has improved refrigerated cost, and the practicality is on the low side.

Disclosure of Invention

The invention aims to solve the defects that the cooling efficiency is low, the cooling cost is increased and the practicability is low due to the fact that all plates are collected together and then put into a cooling mechanism for cooling in the conventional efficient cooling mechanism for producing the glass cloth laminated board.

In order to achieve the purpose, the invention adopts the following technical scheme: a high-efficient cooling body of production glass cloth laminated board, includes two backup pads, the bottom fixedly connected with support column of backup pad, and the top of backup pad installs the cover body, electric telescopic handle is installed respectively to the bottom both sides of cover body, and electric telescopic handle's bottom installs the fan, two servo motor are installed to one side of backup pad, and one side fixedly connected with two first rotating shafts of backup pad, servo motor passes and is connected for the gomphosis between one side of backup pad and first rotating shaft, and one side of first rotating shaft rotates and is connected with first rotating rod, the surface mounting of first rotating rod has first gear, and the bottom gomphosis of first gear is connected with the second gear, the surface mounting of second gear has the conveyer belt, and the top gomphosis of second gear is connected with a plurality of third gears, the surface mounting of third gear has the second rotating rod, and the surface of the second rotating rod is provided with a reinforcing mechanism, the inside of the reinforcing mechanism comprises a plurality of first sleeves, the surfaces of the first sleeve and the second rotating rod are connected, a first return spring is fixedly connected inside the first sleeve, and one side of the first return spring is fixedly connected with a first T-shaped rod, one side of the first T-shaped rod is fixedly connected with a peak plate, one side of the supporting plate is embedded and connected with a first chute, a first sliding block is sleeved and inserted in the first sliding groove, one side of the first sliding block is fixedly connected with a second rotating shaft, and the second rotating shaft is rotatably connected with one side of the second rotating rod, the surface of the second rotating rod is movably connected with a fixed plate, and one side threaded connection of fixed plate has first hand to twist the bolt, the cooler bin is installed to one side of support column, and complementary unit is installed to one side of support column.

As a further description of the above technical solution:

first hand is twisted the bolt and is passed for threaded connection between one side of fixed plate and backup pad, and first hand is twisted the bolt and is passed through and constitute detachable construction between fixed plate and the backup pad.

As a further description of the above technical solution:

the fan passes through to constitute elevation structure between electric telescopic handle and the cover body, first axis of rotation and backup pad between constitution rotating-structure are passed through to first axis of rotation.

As a further description of the above technical solution:

first T type pole passes through to constitute elastic telescopic structure between first reset spring and the first sleeve, and first sleeve is the symmetry about the axis of second dwang.

As a further description of the above technical solution:

the second rotating rod forms a rotating structure through the second rotating shaft and the first sliding block, and the second rotating shaft forms a sliding structure through the first sliding block and the first sliding groove.

As a further description of the above technical solution:

the auxiliary mechanism comprises an installation plate inside, the installation plate is connected with one side of a support column, a second chute is connected with one side of the installation plate in an embedded mode, a second slider is inserted into the second chute in a sleeved mode, a bearing plate is fixedly connected to one side of the second slider, grooves are respectively connected to two sides of the bearing plate in an embedded mode, a first connecting rod is fixedly connected to the inside of each groove, a connecting plate is movably connected to the surface of each first connecting rod, a second hand-screw bolt is connected to one side of each connecting plate in a threaded mode, a placing plate is connected to one side of each connecting plate in an embedded mode, a limiting groove is connected to one side of each placing plate in an embedded mode, a plurality of first baffle plates are fixedly connected to the top end of each placing plate, a second connecting rod is fixedly connected to one side of each first baffle plate, idler wheels, and sheathed tube one side has been seted up a plurality of through-holes, fixedly connected with third spout is surveyed to sheathed tube inner wall one, and the inside cup joints of third spout and inserts and be equipped with the third slider, one side fixedly connected with carriage release lever of third slider, and one side fixedly connected with second sleeve of carriage release lever, the inside fixedly connected with second reset spring of second sleeve, and one side fixedly connected with second T type pole of second reset spring, one side fixedly connected with stopper of carriage release lever, and be connected between the inside of stopper and spacing groove, one side fixedly connected with second baffle of backup pad, and one side threaded connection of second baffle has the third connecting rod to flitch under the fixed surface of third connecting rod is connected with.

As a further description of the above technical solution:

the second hand-operated bolt penetrates through the connecting plate and is in threaded connection with one side of the placing plate, and the second hand-operated bolt penetrates through the connecting plate and forms a detachable structure with the placing plate.

As a further description of the above technical solution:

the bearing board passes through to constitute sliding structure between second slider and the second spout, the connecting plate passes through to constitute flip structure between first connecting rod and the recess, the carriage release lever passes through to constitute sliding structure between third slider and the third spout.

As a further description of the above technical solution:

the second T-shaped rod is movably connected with the inside of the through hole, the second T-shaped rod passes through the through hole and forms a clamping structure with the sleeve, and the second T-shaped rod passes through the second return spring and forms an elastic telescopic structure with the second sleeve.

In summary, due to the adoption of the technical scheme, the invention has the beneficial effects that:

1. according to the invention, under the action of the reinforcing mechanism, the first rotating rod can drive the first gear to rotate through the work of the servo motor, so that the second gear in meshed connection with the bottom end of the first gear can drive the conveyor belt to rotate, the third gear in meshed connection with the top end of the second gear can drive the second rotating rod to move through the rotation of the peak-shaped plate, the plate can be placed on the surface of the peak-shaped plate conveniently, the plate can be cooled through the rotation of the peak-shaped plate conveniently in the process of conveying the plate, the subsequent cooling efficiency can be improved, the first T-shaped rod and the peak-shaped plate are extruded through the first return spring, the peak-shaped plate can be conveniently contacted with the plate, the friction force between the plate and the plate is increased, and the plate can be conveniently conveyed.

2. According to the invention, the second rotating shaft connected to one side of the first sliding block drives the second rotating rod and the peak-shaped plate indirectly connected with the second rotating shaft to move through the movement of the first sliding block in the first sliding groove, so that the distance between the two peak-shaped plates can be conveniently adjusted according to the sizes of different plates, the plates with different sizes can be conveniently conveyed, the plates with different sizes can be conveniently cooled in the conveying process, and the second rotating rod and the peak-shaped plate can be conveniently fixed at specified positions through rotating the first screwed bolt into the fixed plate and the supporting plate, so that the subsequent work is convenient.

3. According to the invention, under the action of the auxiliary mechanism, the placing plate is placed between the two peak-shaped plates, and the roller at the top end of the placing plate rotates on the surface of the second connecting rod, so that the plate is prevented from being clamped between the two peak-shaped plates and influencing the conveying speed of the plate when the plate is conveyed on the surface of the peak-shaped plate.

4. According to the invention, the second sliding block moves in the second sliding groove, so that the placing plate connected with the bearing plate connected with one side of the second sliding block can be moved conveniently, the plate can be moved conveniently according to the distance between the two peak-shaped plates, the plate can be conveyed and cooled conveniently, the third connecting rod rotates on the surface of the second baffle plate, the blanking plate connected with the third connecting rod can be moved conveniently, the blanking plate can be moved to a specified angle conveniently, the plate on the peak-shaped plate can be conveyed to the inside of the cooling box conveniently, and the cooling of the plate can be facilitated.

5. According to the invention, the second T-shaped rod is extruded into the sleeve under the action of the second T-shaped rod, so that the moving rod in the sleeve can slide in the third sliding groove through the third sliding block, one side of the moving rod is conveniently connected with the limiting block and moves to the inside of the limiting groove, the placing plate and the bearing plate are conveniently installed at the appointed position, and the phenomenon that the placing plate and the bearing plate move to influence the conveying and cooling of the plate in the conveying process of the plate is prevented.

Drawings

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a schematic view of the interior of the mask body of the present invention;

FIG. 3 is a schematic diagram of a partial top view of the present invention;

FIG. 4 is a schematic side view of a portion of the conveyor belt of the present invention;

fig. 5 is a schematic view of the inside of the second rotating lever according to the present invention;

FIG. 6 is a side view of the auxiliary mechanism of the present invention;

FIG. 7 is a schematic view of the interior of the bushing of the present invention;

FIG. 8 is a side view of the blanking plate of the present invention;

fig. 9 is a structural schematic diagram of the blanking plate part in a front view.

Illustration of the drawings:

1. a support plate; 2. a support pillar; 3. a cover body; 4. an electric telescopic rod; 5. a fan; 6. a servo motor; 7. a first rotating shaft; 8. a first rotating lever; 9. a first gear; 10. a second gear; 11. a conveyor belt; 12. a third gear; 13. a second rotating lever; 14. a reinforcing mechanism; 1401. a first sleeve; 1402. a first return spring; 1403. a first T-bar; 1404. a peak plate; 1405. a first chute; 1406. a first slider; 1407. a second rotating shaft; 1408. a fixing plate; 1409. screwing the bolt by a first hand; 15. an auxiliary mechanism; 1501. mounting a plate; 1502. a second chute; 1503. a second slider; 1504. a carrier plate; 1505. a groove; 1506. a first connecting rod; 1507. a connecting plate; 1508. screwing a bolt by a second hand; 1509. placing the plate; 1510. a limiting groove; 1511. a first baffle plate; 1512. a second connecting rod; 1513. a roller; 1514. a sleeve; 1515. a through hole; 1516. a third chute; 1517. a third slider; 1518. a travel bar; 1519. a second sleeve; 1520. a second return spring; 1521. a second T-bar; 1522. a limiting block; 1523. a second baffle; 1524. a third connecting rod; 1525. a blanking plate; 16. and a cooling tank.

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. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

As shown in fig. 1-9, an efficient cooling mechanism for producing a glass cloth laminated board comprises two supporting plates 1, wherein the bottom end of each supporting plate 1 is fixedly connected with a supporting column 2, the top end of each supporting plate 1 is provided with a cover body 3, two sides of the bottom end of each cover body 3 are respectively provided with an electric telescopic rod 4, the bottom end of each electric telescopic rod 4 is provided with a fan 5, one side of each supporting plate 1 is provided with two servo motors 6, one side of each supporting plate 1 is fixedly connected with two first rotating shafts 7, each servo motor 6 penetrates through the supporting plate 1 to be in embedded connection with one side of each first rotating shaft 7, one side of each first rotating shaft 7 is rotatably connected with a first rotating rod 8, the surface of each first rotating rod 8 is provided with a first gear 9, the bottom end of each first gear 9 is in engaged connection with a second gear 10, the surface of each second gear 10 is provided with a conveying belt 11, and the top, a second rotating rod 13 is installed on the surface of the third gear 12, a reinforcing mechanism 14 is installed on the surface of the second rotating rod 13, a plurality of first sleeves 1401 are arranged inside the reinforcing mechanism 14, the first sleeves 1401 are connected with the surface of the second rotating rod 13, a first return spring 1402 is fixedly connected inside the first sleeves 1401, a first T-shaped rod 1403 is fixedly connected to one side of the first return spring 1402, a peak-shaped plate 1404 is fixedly connected to one side of the first T-shaped rod 1403, a first sliding groove 1405 is embedded and connected to one side of the supporting plate 1, a first sliding block 1406 is inserted and connected inside the first sliding groove 1405 in a sleeved mode, a second rotating shaft 1407 is fixedly connected to one side of the first sliding block 1406, the second rotating shaft 1407 is rotatably connected with one side of the second rotating rod 13, a fixing plate 1408 is movably connected to the surface of the second rotating rod 13, and a first hand-screwing bolt 1409 is connected to one side of the fixing plate 1408, a cooling tank 16 is installed at one side of the support column 2, and an auxiliary mechanism 15 is installed at one side of the support column 2. The servo motor 6 can control the speed and position accuracy accurately, can convert the voltage signal into torque and rotating speed to drive the controlled object, the rotating speed of the rotor of the servo motor 6 is controlled by the input signal and can react quickly, in the automatic control system, the servo motor 6 is used as an executing element and has the characteristics of small electromechanical time constant, high linearity, starting voltage and the like, the received electric signal can be converted into the angular displacement or the angular speed on the motor shaft for output, the servo motor 6 is controlled by a control switch, and the first gear 9 and the third gear 12 are both connected with the bottom end of the second gear 10 and are not connected with the top end of the second gear.

As shown in fig. 1 to 9, the first screw 1409 passes through the fixing plate 1408 and is threadedly coupled to one side of the support plate 1, the first screw 1409 passes through the fixing plate 1408 and is detachably coupled to the support plate 1, the first screw 1409 is rotated into the fixing plate 1408 and the interior of the support plate 1, so that the second rotating rod 13 is fixed and prevented from moving, and the second rotating rod 13 is movably coupled to the interior of the fixing plate 1408 and can rotate within the fixing plate 1408.

As shown in fig. 1 to 9, the fan 5 passes through the lifting structure formed between the electric telescopic rod 4 and the cover 3, the first rotating rod 8 passes through the rotating structure formed between the first rotating shaft 7 and the supporting plate 1, the fan 5 is convenient for cooling the plate on the surface of the peak-shaped plate 1404, the subsequent cooling efficiency can be improved, and the electric telescopic rod 4 is convenient for the lifting function of the fan 5.

As shown in fig. 1 to 9, the first T-shaped rod 1403 is elastically telescopic through the first return spring 1402 and the first sleeve 1401, and the first sleeve 1401 is symmetrical about the central axis of the second rotating rod 13, and the first return spring 1402 facilitates pressing the first T-shaped rod 1403 and the peak-shaped plate 1404, facilitating contacting the peak-shaped plate 1404 with the surface of the plate, facilitating increasing the friction between the peak-shaped plate 1404 and the surface of the plate, and facilitating conveying the plate.

As shown in fig. 1 to 9, the second rotating rod 13 forms a rotating structure through the second rotating shaft 1407 and the first sliding block 1406, and the second rotating shaft 1407 forms a sliding structure through the first sliding block 1406 and the first sliding groove 1405, so that the first sliding block 1406 slides inside the first sliding groove 1405, and the second rotating rod 13 drives the peak plate 1404 to move, thereby facilitating adjustment according to different sizes of the plate materials.

As shown in fig. 6-9, the auxiliary mechanism 15 includes a mounting plate 1501 inside, the mounting plate 1501 is connected to one side of the supporting column 2, a second sliding chute 1502 is embedded and connected to one side of the mounting plate 1501, a second sliding block 1503 is inserted and connected to the inside of the second sliding chute 1502, a bearing plate 1504 is fixedly connected to one side of the second sliding block 1503, grooves 1505 are respectively embedded and connected to both sides of the bearing plate 1504, a first connecting rod 1506 is fixedly connected to the inside of the groove 1505, a connecting plate 1507 is movably connected to the surface of the first connecting rod 1506, a second hand screw bolt 1508 is threadedly connected to one side of the connecting plate 1507, a placing plate 1509 is connected to one side of the placing plate 1507, a limiting groove 1510 is embedded and connected to one side of the placing plate 1509, a plurality of first baffles 1511 are fixedly connected to the top end of the placing plate 1509, a second connecting rod 1512 is fixedly connected to one side of the first baffles 1511, and, a sleeve 1514 is mounted on one side of the mounting plate 1501, a plurality of through holes 1515 are formed in one side of the sleeve 1514, a third chute 1516 is fixedly connected to one side of the inner wall of the sleeve 1514, a third slider 1517 is inserted into the third chute 1516 in a sleeved mode, a moving rod 1518 is fixedly connected to one side of the third slider 1517, a second sleeve 1519 is fixedly connected to one side of the moving rod 1518, a second return spring 1520 is fixedly connected to the inside of the second sleeve 1519, a second T-shaped rod 1521 is fixedly connected to one side of the second return spring 1520, a limit block 1522 is fixedly connected to one side of the moving rod 1518, the limit block 1522 is connected to the inside of the limit groove 1510, a second baffle 1523 is fixedly connected to one side of the support plate 1, a third connecting rod 1524 is connected to one side of the second baffle 3 in a threaded mode, a blanking plate 1525 is fixedly connected to the surface of the third connecting rod 1524, the roller 1523 rolls on the surface of, the sheet material can be easily transported and placed between the two peak plates 1404 to prevent the sheet material from being jammed due to an excessive distance between the two peak plates 1404.

As shown in fig. 6 to 9, the second hand-screw bolt 1508 is screwed between the connecting plate 1507 and one side of the placing plate 1509, and the second hand-screw bolt 1508 forms a detachable structure between the connecting plate 1507 and the placing plate 1509, so that the placing plate 1509 can be conveniently installed between the top end of the loading plate 1504 and the two peak-shaped plates 1404 by turning the second hand-screw bolt 1508 inside the connecting plate 1507 and the placing plate 1509.

As shown in fig. 6-9, the carrier plate 1504 forms a sliding structure between the second slider 1503 and the second sliding slot 1502, the connecting plate 1507 forms an overturning structure between the first connecting rod 1506 and the groove 1505, the moving rod 1518 forms a sliding structure between the third slider 1517 and the third sliding slot 1516, and the second slider 1503 moves inside the second sliding slot 1502, so that the carrier plate 1504 can move the placing plate 1509 and the roller 1513 together, and can move and adjust the two peak plates 1404 according to the distance therebetween.

As shown in fig. 6-9, the second T-shaped rod 1521 is movably connected to the inside of the through hole 1515, the second T-shaped rod 1521 forms a snap-fit structure with the sleeve 1514 through the through hole 1515, the second T-shaped rod 1521 forms an elastic telescopic knot with the second sleeve 1519 through the second return spring 1520, the second return spring 1520 facilitates the second T-shaped rod 1521 to pop out through the through hole 1515, facilitates the movement of the movable rod 1518, and facilitates the limitation of the limitation block 1522 connected to the movable rod 1518 to the inside of the limitation groove 1510.

The working principle is as follows: when the plate cooling device is used, firstly, the servo motor 6 works to enable the first rotating rod 8 to drive the first gear 9 to rotate, so that the second gear 10 meshed and connected with the bottom end of the first gear 9 drives the conveyor belt 11 to rotate, the second gear 10 rotates, the third gear 12 meshed and connected with the top end of the second gear can drive the second rotating rod 13 to move, a plate is placed on the surface of the peak-shaped plate 1404 and is cooled by the fan 5 in the plate conveying process through the rotation of the peak-shaped plate 1404, the subsequent cooling efficiency can be improved, the first return spring 1402 extrudes the first T-shaped rod 1403 and the peak-shaped plate 1404 to facilitate the contact between the peak-shaped plate 1404 and the plate, the friction force between the plate and the plate is increased to facilitate the conveying of the plate, the first slide block 1406 moves inside the first sliding groove 1405, and the second rotating shaft 1407 connected with one side of the first slide block 1406 can drive the second rotating rod 13 and the second rotating shaft 1407 connected with the first slide block 1406 The peak-shaped plates 1404 are moved to adjust the distance between the two peak-shaped plates 1404 according to the sizes of different plates, to facilitate the transport of the plates of different sizes and to facilitate the cooling thereof during the transport, the second rotating rod 13 and the peak-shaped plates 1404 are fixed at the designated positions by rotating the first hand-threaded bolt 1409 into the fixing plate 1408 and the inside of the supporting plate 1 to facilitate the following work, the plates are prevented from being stuck between the two peak-shaped plates 1404 and affecting the transport speed thereof when the plates are transported on the surfaces of the peak-shaped plates 1404 by placing the placing plate 1509 between the two peak-shaped plates 1404 and rotating the plates on the surfaces of the second connecting rods 1512 by the roller 1513 at the tips thereof, the connecting plate 1507 is moved to the side of the placing plate 1509 by the reverse movement of the connecting plate 1507 on the surfaces of the first connecting rods 1506, and the placing plate 1509 and the inside of the connecting plate 1507 are rotated by the second hand-threaded bolt 1508, the placement plate 1509 can be conveniently installed at a designated position between the two peak-shaped plates 1404, the second slider 1503 can move inside the second sliding groove 1502, the placement plate 1509 connected with the bearing plate 1504 connected with one side of the second slider 1503 can be conveniently moved, the two peak-shaped plates 1404 can be conveniently moved according to the distance between the two peak-shaped plates 1404, the conveying of the plate materials and the cooling of the plate materials can be conveniently realized, the third connecting rod 1524 is rotated on the surface of the second baffle 1523, the blanking plate 1525 connected with the third connecting rod 1524 can be moved, the blanking plate 1525 can be conveniently moved to a designated angle, the plate materials on the peak-shaped plates 1404 can be conveniently conveyed inside the cooling box 16 and can be conveniently cooled, the second T-shaped rod 1521 can be extruded inside the sleeve 1514, the moving rod 1518 inside the second T-shaped rod 1521 can be conveniently slid inside the third sliding groove 1516 through the third slider 1517, the moving rod 1518 side connected with the limit block 1522 can be conveniently moved inside the limit groove 1510, the placing plate 1509 and the bearing plate 1504 are conveniently installed at the designated positions, and the phenomenon that the moving of the placing plate 1509 and the bearing plate 1504 affects the conveying and cooling of the plates in the conveying process of the plates is prevented, so that the working principle of the invention is completed.

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 the technical solutions and the inventive concepts thereof according to the present invention should be equivalent or changed within the scope of the present invention.

Claims (9)

1. The utility model provides a production glass cloth laminated board's high-efficient cooling body, including two backup pads (1), its characterized in that: the bottom of the supporting plate (1) is fixedly connected with a supporting column (2), the top end of the supporting plate (1) is provided with a cover body (3), two electric telescopic rods (4) are respectively arranged on two sides of the bottom end of the cover body (3), a fan (5) is arranged at the bottom end of each electric telescopic rod (4), two servo motors (6) are arranged on one side of the supporting plate (1), two first rotating shafts (7) are fixedly connected to one side of the supporting plate (1), the servo motors (6) penetrate through the supporting plate (1) and one side of each first rotating shaft (7) to be connected in an embedded mode, one side of each first rotating shaft (7) is rotatably connected with a first rotating rod (8), a first gear (9) is arranged on the surface of each first rotating rod (8), a second gear (10) is meshed with the bottom end of the first gear (9), a conveying belt (11) is arranged on the surface of the, a plurality of third gears (12) are connected to the top end of the second gear (10) in a meshing manner, a second rotating rod (13) is installed on the surface of each third gear (12), a reinforcing mechanism (14) is installed on the surface of each second rotating rod (13), a plurality of first sleeves (1401) are arranged inside each reinforcing mechanism (14), the first sleeves (1401) are connected with the surface of each second rotating rod (13), a first return spring (1402) is fixedly connected inside each first sleeve (1401), a first T-shaped rod (1403) is fixedly connected to one side of each first return spring (1402), a peak-shaped plate (1404) is fixedly connected to one side of each first T-shaped rod (1403), a first sliding groove (1405) is connected to one side of the support plate (1) in an embedded manner, a first sliding block (1406) is inserted into each first sliding groove (1405), and a second rotating shaft (1407) is fixedly connected to one side of each first sliding block (1406), and be connected for rotating between one side of second axis of rotation (1407) and second dwang (13), the surperficial swing joint of second dwang (13) has fixed plate (1408), and one side threaded connection of fixed plate (1408) has first hand to twist bolt (1409), cooler bin (16) are installed to one side of support column (2), and complementary unit (15) are installed to one side of support column (2).

2. The efficient cooling mechanism for producing glass cloth laminated plate according to claim 1, wherein: the first hand-operated bolt (1409) penetrates through the fixing plate (1408) and is in threaded connection with one side of the support plate (1), and the first hand-operated bolt (1409) passes through the fixing plate (1408) and forms a detachable structure with the support plate (1).

3. The efficient cooling mechanism for producing glass cloth laminated plate according to claim 1, wherein: fan (5) pass through electric telescopic handle (4) and constitute elevation structure between the cover body (3), first axis of rotation (8) pass through and constitute revolution mechanic between first axis of rotation (7) and backup pad (1).

4. The efficient cooling mechanism for producing glass cloth laminated plate according to claim 1, wherein: the first T-shaped rod (1403) and the first sleeve (1401) form an elastic telescopic structure through the first return spring (1402), and the first sleeve (1401) is symmetrical about the central axis of the second rotating rod (13).

5. The efficient cooling mechanism for producing glass cloth laminated plate according to claim 1, wherein: the second rotating rod (13) forms a rotating structure through the second rotating shaft (1407) and the first sliding block (1406), and the second rotating shaft (1407) forms a sliding structure through the first sliding block (1406) and the first sliding groove (1405).

6. The efficient cooling mechanism for producing glass cloth laminated plate according to claim 1, wherein: the inside of auxiliary mechanism (15) is including mounting panel (1501), and is connected between one side of mounting panel (1501) and support column (2), one side gomphosis of mounting panel (1501) is connected with second spout (1502), and the inside cup jointing of second spout (1502) is inserted and is equipped with second slider (1503), one side fixedly connected with loading board (1504) of second slider (1503), and the both sides of loading board (1504) gomphosis respectively are connected with recess (1505), the inside fixedly connected with first connecting rod (1506) of recess (1505), and the surface swing joint of first connecting rod (1506) has connecting plate (1507), one side threaded connection of connecting plate (1507) has second hand-operated bolt (1508), and one side of connecting plate (1507) is connected with places board (1509), one side gomphosis of placing board (1509) is connected with spacing groove (1510), a plurality of first baffles (1511) are fixedly connected to the top end of the placing plate (1509), a second connecting rod (1512) is fixedly connected to one side of each first baffle (1511), a roller (1513) is movably connected to the surface of each second connecting rod (1512), a sleeve (1514) is installed on one side of the mounting plate (1501), a plurality of through holes (1515) are formed in one side of each sleeve (1514), a third sliding groove (1516) is fixedly connected to the inner wall of each sleeve (1514), a third sliding block (1517) is inserted into the inner portion of each third sliding groove (1516) in a sleeved mode, a moving rod (1518) is fixedly connected to one side of each third sliding block (1517), a second sleeve (1519) is fixedly connected to one side of each moving rod (1518), a second reset spring (1520) is fixedly connected to the inner portion of each second sleeve (1519), and a second T-shaped rod (1521) is fixedly connected to one side of each second reset spring (1520), one side fixedly connected with stopper (1522) of carriage release lever (1518), and be connected between the inside of stopper (1522) and spacing groove (1510), one side fixedly connected with second baffle (1523) of backup pad (1), and one side threaded connection of second baffle (1523) has third connecting rod (1524) to the fixed surface of third connecting rod (1524) is connected with down flitch (1525).

7. The efficient cooling mechanism for producing glass cloth laminated plate according to claim 6, wherein: the second hand-operated bolt (1508) penetrates through the connecting plate (1507) and is in threaded connection with one side of the placing plate (1509), and the second hand-operated bolt (1508) forms a detachable structure through the connecting plate (1507) and the placing plate (1509).

8. The efficient cooling mechanism for producing glass cloth laminated plate according to claim 6, wherein: the bearing plate (1504) forms a sliding structure through the second sliding block (1503) and the second sliding groove (1502), the connecting plate (1507) forms a turnover structure through the first connecting rod (1506) and the groove (1505), and the moving rod (1518) forms a sliding structure through the third sliding block (1517) and the third sliding groove (1516).

9. The efficient cooling mechanism for producing glass cloth laminated plate according to claim 6, wherein: the second T-shaped rod (1521) is movably connected with the inside of the through hole (1515), the second T-shaped rod (1521) forms a clamping structure with the sleeve (1514) through the through hole (1515), and the second T-shaped rod (1521) forms an elastic telescopic structure with the second sleeve (1519) through the second return spring (1520).

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