CN115722422A - Thermal-protective coating machine is used in production of glass fiber heat-insulating film - Google Patents

Abstract

The invention relates to a heat insulation layer coating machine, in particular to a heat insulation layer coating machine for producing a glass fiber heat insulation film. The heat insulation layer coating machine for producing the glass fiber heat insulation film needs to be designed, and the heat insulation layer coating machine can extrude and completely permeate the coated vermiculite suspension into the glass fiber film and improve the coating quality of a heat insulation layer. The utility model provides a production of glass fiber thermal-insulated membrane is with insulating layer coating machine, includes mounting panel, landing leg and u type seat etc. and mounting panel bottom rigid coupling has the landing leg, and mounting panel trailing flank bilateral symmetry rigid coupling has and is used for the glass fiber membrane to carry out the u type seat of placing. According to the invention, the head end of the glass fiber membrane penetrates through the coating component and the drying component to be fixed on the winding drum, the winding mechanism is started, so that the glass fiber membrane moves rightwards to be coated, the winding mechanism also drives the pressing mechanism to operate to be in contact with the glass fiber membrane, and the pressing mechanism extrudes the vermiculite suspension liquid, so that the vermiculite suspension liquid completely penetrates into the glass fiber membrane to form the heat-insulating layer, and the coating quality of the heat-insulating layer is improved.

Description

Thermal-protective coating machine is used in production of glass fiber heat-insulating film

Technical Field

The invention relates to a heat insulation layer coating machine, in particular to a heat insulation layer coating machine for producing a glass fiber heat insulation film.

Background

In the process of manufacturing the glass fiber heat insulation film, vermiculite suspension is generally required to be coated on the glass fiber film to complete coating treatment, and then the glass fiber heat insulation film is manufactured by drying.

At present, vermiculite suspension is mostly coated on a glass fiber membrane through a coating machine to form a heat insulation layer, but the coating machine only coats the vermiculite suspension on the glass fiber membrane and then dries the glass fiber membrane, and as the vermiculite suspension is coated on the glass fiber membrane, part of the vermiculite suspension does not completely permeate into the glass fiber membrane before drying, so that the quality of the manufactured heat insulation layer is poor.

Therefore, a heat insulation layer coating machine for producing a glass fiber heat insulation film, which can extrude and completely permeate the coated vermiculite suspension into a glass fiber film and improve the coating quality of the heat insulation layer, needs to be designed.

Disclosure of Invention

In order to overcome the defect that partial vermiculite suspension liquid is not completely permeated into a glass fiber membrane before drying because the vermiculite suspension liquid is coated on the glass fiber membrane, the quality of a manufactured heat insulation layer is poor, the invention provides the heat insulation layer coating machine for producing the glass fiber heat insulation membrane, which can extrude the coated vermiculite suspension liquid to completely permeate into the glass fiber membrane and improve the coating quality of the heat insulation layer.

The invention is realized by the following technical approaches:

the utility model provides a thermal-protective layer coating machine is used in production of glass fiber heat-insulating film, including the mounting panel, the landing leg, u type seat, coating components and stoving subassembly, mounting panel bottom rigid coupling has the landing leg, mounting panel trailing flank bilateral symmetry rigid coupling has the u type seat that is used for the glass fiber membrane to carry out to place, the rigid coupling has coating components in the middle of the mounting panel top, the rigid coupling has the stoving subassembly in the middle of the mounting panel top front side, still including winding mechanism and pressure whole mechanism, be provided with on the mounting panel and be used for driving the winding mechanism that the glass fiber membrane moved forward and is coated, be provided with between mounting panel and the winding mechanism and be used for with vermiculite suspension hydraulic pressure extrusion to the intraformational pressure whole mechanism of glass fiber.

Further explanation, winding mechanism is including the fixing base, the sliding seat, first reset spring, the blowing axle, hexagonal pole and motor, mounting panel leading flank rigid coupling has the fixing base, the slidingtype sliding seat that is connected with in the fixing base trailing flank left side, the blowing axle that is used for placing the winding drum is installed in removable rotation between sliding seat and the fixing base right side, both ends all open the hexagonal groove about the blowing axle, be connected with first reset spring between sliding seat right side and the fixing base inboard, the cross-under of fixing base right side rotary type has and is used for driving blowing axle pivoted hexagonal pole, the hexagonal pole left end is located the hexagonal inslot on blowing axle right side, mounting panel bottom right front side all the rigid coupling has the motor, pass through synchronous belt drive between the output shaft of motor and the hexagonal pole.

The pressing mechanism comprises a support frame, a sliding frame, a second reset spring, a pressing plate, a first pressurizing spring, a first rotating rod, an electromagnetic wheel, a trigger plate and a rotating shaft, wherein the support frame is fixedly connected to the front side of the top of the mounting plate, the sliding frame is connected to the rear portion of the support frame in a sliding mode in a penetrating mode, the second reset spring is connected between the left side and the right side of the inner top of the sliding frame and the left side and the right side of the rear portion of the support frame respectively, the pressing plate for extruding vermiculite suspension is connected to the bottom of the sliding frame in a penetrating mode in a sliding mode, the first pressurizing spring is connected between the inner bottom of the pressing plate and the outer bottom of the sliding frame in a bilateral symmetry mode, the first rotating rod is connected to the front portion of the support frame in a penetrating mode in a rotating mode, the electromagnetic wheel is fixedly connected to the middle of the first rotating rod in a bilateral symmetry mode, the trigger plate used for driving the sliding frame to move downwards is sleeved on the middle of the first rotating rod, the trigger plate is in magnetic contact with the left side and right side of the outer side of the support frame, the rotating shaft is in a front side of the rotating side, synchronous belt transmission mode transmission is used for transmitting the output shaft transmission between the middle of the rotating shaft and the first rotating rod.

The device comprises a glass fiber membrane, a guide plate, a fixing frame, a sponge plate and a guide rod, wherein the fixing frame is fixedly connected to the rear side of the top of the mounting plate, the sponge plate used for removing impurities on the glass fiber membrane is connected to the fixing frame in a sliding mode, the guide rod is fixedly connected to the lower portions of the left side and the right side of the outer side of the sponge plate, the second rotating rod is connected to the rear side of the bottom of the mounting plate in a rotating mode, the guide plate used for driving the guide rod to move left and right is fixedly sleeved on the left side and the right side of the second rotating rod, the guide plates on the left side and the right side are respectively in contact with the outer ends of the guide rods on the left side and the right side, and the right end of the second rotating rod and an output shaft of a motor are in synchronous belt transmission mode.

The glass fiber membrane guiding device comprises a glass fiber membrane tensioning mechanism, and is characterized by further comprising a clamping mechanism used for tensioning the glass fiber membrane, wherein the clamping mechanism comprises a mounting seat, rubber wheels, a sliding block and a second pressurizing spring, the mounting seat is fixedly connected to the rear side of the top of the mounting plate, the mounting seat is located on the rear side of a fixing frame, the sliding block is connected to the left side and the right side of the mounting seat in a sliding mode, the second pressurizing spring is connected between the top of the sliding block on the left side and the right side of the mounting seat and the inner side of the mounting seat, the inner side faces of the sliding block on the left side and the right side of the mounting seat are connected with the rubber wheels in a rotating mode, and the lower portions of the left side face and the right side of the mounting seat are also connected with the rubber wheels in a rotating mode.

Further explanation, still including being used for carrying out the pressure adjustment mechanism who adjusts to the extrusion power, pressure adjustment mechanism is including a screw thread section of thick bamboo, screw thread carousel and limiting plate, and carriage left and right sides lower part all rigid coupling has a screw thread section of thick bamboo, and all threaded rotation is connected with the screw thread carousel on the screw thread section of thick bamboo of the left and right sides, and left and right sides lower part all rigid coupling has and is used for carrying out spacing limiting plate to the screw thread carousel in the support frame, and the limiting plate corresponds with the screw thread carousel.

The drying assembly comprises a drying assembly, a glass fiber heat insulation film and a guide mechanism, wherein the glass fiber heat insulation film is arranged in the drying assembly, the guide mechanism is used for guiding the glass fiber heat insulation film and comprises a hinged frame and a guide wheel, the front side and the rear side of the lower portion of the left side surface and the rear side of the lower portion of the right side surface of the drying assembly are fixedly connected with two hinged frames, and the guide wheel used for guiding the glass fiber heat insulation film is sleeved in the middle of each hinged frame in a rotating mode.

Further, the device also comprises scraping plates, and the scraping plates for scraping redundant vermiculite suspensions on two sides of the glass fiber heat insulation film are fixedly connected to the front side of the bottom in the support frame in a bilateral symmetry mode.

The invention has the remarkable advantages that:

1. the head end of the glass fiber membrane penetrates through the coating component and the drying component to be fixed on the winding drum, the winding mechanism is started, the glass fiber membrane is enabled to move rightwards to be coated, the winding mechanism further drives the pressing mechanism to operate to be in contact with the glass fiber membrane, the pressing mechanism extrudes the vermiculite suspension liquid, the vermiculite suspension liquid is enabled to completely penetrate into the glass fiber membrane to form the heat insulation layer, and the coating quality of the heat insulation layer is improved.

2. Under the effect of clearance mechanism, can clear away the impurity on the glass fiber membrane before the coating, the glass fiber after the clearance impurity coats again, prevents to have impurity influence coating on the glass fiber membrane, has guaranteed the coating quality of glass fiber membrane.

3. Under the effect of the material clamping mechanism, the glass fiber film can be coated under the condition of tension all the time, so that the glass fiber film is prevented from loosening, and the glass fiber film can be uniformly coated.

Drawings

Fig. 1 is a schematic perspective view of a first perspective structure according to the present invention.

Fig. 2 is a perspective view of a second perspective structure according to the present invention.

Fig. 3 is a partial perspective view of the present invention.

Fig. 4 is a schematic view of a first-view perspective structure of the winding mechanism of the present invention.

Fig. 5 is a schematic view of a second perspective structure of the winding mechanism of the present invention.

Fig. 6 is a schematic partial perspective view of the winding mechanism of the present invention.

Fig. 7 is a schematic perspective view of the pressing mechanism of the present invention.

Fig. 8 is a schematic perspective view of the cleaning mechanism of the present invention.

Fig. 9 is a schematic perspective view of a part of the cleaning mechanism of the present invention.

Fig. 10 is a schematic perspective view of a first clamping mechanism of the present invention.

Fig. 11 is a schematic perspective view of a second clamping mechanism according to the present invention.

Fig. 12 is a schematic perspective view of the pressure adjustment mechanism of the present invention.

Fig. 13 is a schematic perspective view of the guide mechanism of the present invention.

Reference numbers in the drawings: 1. mounting plate, 2, supporting leg, 3, u-shaped seat, 4, coating component, 5, drying component, 6, winding mechanism, 61, fixing seat, 62, sliding seat, 63, first return spring, 64, discharging shaft, 65, hexagonal rod, 67, motor, 7, pressing mechanism, 71, supporting frame, 72, sliding frame, 73, second return spring, 74, pressing plate, 75, first pressure spring, 76, first rotating rod, 77, electromagnetic wheel, 78, trigger plate, 79, rotating shaft, 8, cleaning mechanism, 81, second rotating rod, 82, guide disc, 83, fixing frame, 84, sponge plate, 85, guide rod, 9, clamping mechanism, 91, mounting seat, 92, rubber wheel, 93, sliding block, 94, second pressure spring, 10, pressure adjusting mechanism, 101, threaded cylinder, 102, threaded rotary disc, 103, limiting plate, 11, guide mechanism, 111, hinged frame, 112, guide wheel, 12, scraper.

Detailed Description

It is to be noted that, in the case of the different described embodiments, identical components are provided with the same reference numerals or the same component names, wherein the disclosure contained in the entire description can be transferred to identical components having the same reference numerals or the same component names in a meaningful manner. The positional references selected in the description, such as upper, lower, lateral, etc., refer also to the directly described and illustrated figures and are to be read into the new position in the sense of a change in position.

Example 1

A coating machine for a heat insulation layer for producing a glass fiber heat insulation film comprises a mounting plate 1, supporting legs 2, u-shaped seats 3, coating components 4, drying components 5, a rolling mechanism 6 and a pressing mechanism 7, please refer to fig. 1-7, wherein the supporting legs 2 are mounted at the bottom of the mounting plate 1 in a welding connection mode, the u-shaped seats 3,u type seats 3 are fixedly connected to the left side and the right side of the rear side face of the mounting plate 1 in a bilateral symmetry mode and are used for placing the glass fiber film, the coating components 4 are fixedly connected to the middle of the top of the mounting plate 1, the drying components 5 are fixedly connected to the middle of the front side of the top of the mounting plate 1, the rolling mechanism 6 is arranged on the mounting plate 1, when the rolling mechanism 6 operates, the rolling mechanism 6 can drive the glass fiber film to move forwards to be coated, the pressing mechanism 7 is arranged between the mounting plate 1 and the rolling mechanism 6, and when the pressing mechanism 7 operates to enable vermiculite to be hydraulically pressed into the glass fiber film in a suspending mode.

The winding mechanism 6 includes a fixed seat 61, a sliding seat 62, a first return spring 63, a discharging shaft 64, a hexagonal rod 65 and a motor 67, please refer to fig. 1-6, the fixed seat 61 is installed on the front side of the mounting plate 1 by welding, the sliding seat 62 is slidably connected to the left side of the rear side in the fixed seat 61, the discharging shaft 64 is detachably installed between the sliding seat 62 and the right side of the fixed seat 61, the discharging shaft 64 can place the winding drum, hexagonal grooves are formed at the left and right ends of the discharging shaft 64, the first return spring 63 is connected between the right side of the sliding seat 62 and the inner side of the fixed seat 61, the hexagonal rod 65 is rotatably connected to the right side of the fixed seat 61 in a penetrating manner, the left end of the hexagonal rod 65 is located in the hexagonal groove at the right side of the discharging shaft 64, when the hexagonal rod 65 rotates, the hexagonal rod 65 can drive the discharging shaft 64 to rotate, the motor 67 is fixedly connected to the right front side of the bottom of the mounting plate 1, and the output shaft of the motor 67 is in synchronous belt transmission with the hexagonal rod 65.

The pressing and finishing mechanism 7 comprises a support frame 71, a sliding frame 72, a second return spring 73, a pressing plate 74, a first pressurizing spring 75, a first rotating rod 76, an electromagnetic wheel 77, a trigger plate 78 and a rotating shaft 79, please refer to fig. 1, 2, 3 and 7, the support frame 71 is installed on the front side of the top of the mounting plate 1 in a welding connection mode, the sliding frame 72 is connected in a sliding mode in the rear of the support frame 71 in a penetrating mode, the second return spring 73 is connected between the left side and the right side of the top of the sliding frame 72 and the left side and the right side of the rear of the support frame 71 respectively, the pressing plate 74 is connected in a sliding mode in the bottom of the sliding frame 72 in a penetrating mode, when the pressing plate 74 moves downwards, the pressing plate 74 can realize the extrusion of vermiculite suspension, bilateral symmetry is connected with first compression spring 75 between bottom and the outer bottom of carriage 72 in the clamp plate 74, the cross-under of the anterior rotary type of support frame 71 has first bull stick 76, first bull stick 76 middle part bilateral symmetry rigid coupling has electromagnetic wheel 77, the cover of first bull stick 76 middle part rotary type is equipped with trigger plate 78, trigger plate 78 and the magnetic contact of left and right sides electromagnetic wheel 77, when trigger plate 78 downswing, trigger plate 78 can realize driving carriage 72 and move down, the outer right flank front side of support frame 71 is connected with pivot 79 of rotary type, pass through synchronous belt drive between pivot 79 right side and the output shaft of motor 67, pass through gear drive between pivot 79 middle part and the first bull stick 76 right side.

Firstly, a roll of glass fiber membrane is placed between a left side u-shaped seat 3 and a right side u-shaped seat 3, a winding drum is placed on a winding mechanism 6, the head end of the glass fiber membrane is pulled to penetrate through a coating component 4 and a drying component 5 to be fixed on the winding drum, the drying component 5 and the coating component 4 are started, vermiculite suspension is coated on the glass fiber membrane by the coating component 4, meanwhile, the winding mechanism 6 is started, the winding mechanism 6 operates to drive the winding drum to rotate reversely, the winding drum rotates reversely to drive the glass fiber membrane to move forwards to be wound, the glass fiber membrane moves forwards to be coated with the vermiculite suspension continuously, the winding mechanism 6 also operates to drive a pressing mechanism 7 to operate, the pressing mechanism 7 operates to contact with a glass limiting membrane, when the glass fiber membrane coated with the right vermiculite suspension moves forwards to contact with the pressing mechanism 7, the pressing mechanism 7 presses the vermiculite suspension into the glass fiber membrane, the vermiculite suspension completely penetrates into the glass fiber membrane to form a heat insulation layer, the quality of the heat insulation layer coating is improved, the glass fiber membrane coated with the heat insulation layer moves forwards to be dried by the drying component 5, the glass fiber membrane is rolled into the heat insulation membrane, the glass fiber membrane 6, and the vermiculite is rolled into the heat insulation layer to form the heat insulation layer repeatedly. When a roll of glass fiber film is manufactured into the glass fiber heat-insulating film, the winding mechanism 6 is closed, the winding mechanism 6 stops driving the winding roll to rotate reversely, the winding mechanism 6 also stops driving the pressing mechanism 7 to operate, the pressing mechanism 7 operates to reset, the drying component 5 and the coating component 4 are closed, and the winding roll can be taken down from the winding mechanism 6 to perform subsequent treatment on the glass fiber heat-insulating film.

When a roll of glass fiber film is placed between the left and right u-shaped seats 3, the sliding seat 62 is pulled to move leftward, the first return spring 63 is compressed, the sliding seat 62 moves leftward to drive the discharging shaft 64 to move leftward, the discharging shaft 64 moves leftward to be separated from the contact with the hexagonal rod 65, the discharging shaft 64 can be taken down, the winding drum is sleeved on the discharging shaft 64, the discharging shaft 64 is inserted back to the sliding seat 62, the sliding seat 62 is loosened, the sliding seat 62 moves rightward to return and drive the discharging shaft 64 to move rightward to return under the action of the first return spring 63, the discharging shaft 64 moves rightward to return and is sleeved on the hexagonal rod 65, the head end of the glass fiber film is pulled to penetrate through the coating component 4 and the drying component 5 to be fixed on the winding drum, the motor 67 is started, the motor 67 drives the hexagonal rod 65 to rotate reversely through synchronous belt transmission, the hexagonal rod 65 rotates reversely to drive the discharging shaft 64 to rotate reversely, the discharging shaft 64 rotates reversely to drive the winding drum, the winding drum rotates reversely to drive the glass fiber film to move forwards to be coated with suspension, and when the glass fiber film is manufactured into a heat insulation glass fiber film. When a roll of glass fiber film is manufactured into the glass fiber heat insulation film, the motor 67 is turned off, the hexagonal rod 65 stops driving the discharging shaft 64 to rotate reversely, the discharging shaft 64 stops driving the winding drum to rotate reversely, the discharging shaft 64 is separated from the hexagonal rod 65 to contact with the hexagonal rod according to the operation, and then the winding drum is taken down to perform subsequent treatment on the glass fiber heat insulation film.

When the motor 67 is started, the left electromagnetic wheel 77 and the right electromagnetic wheel 77 are started, the left electromagnetic wheel 77 and the right electromagnetic wheel 77 attract the trigger plate 78 through magnetic force, the motor 67 rotates reversely through a synchronous belt to drive the rotating shaft 79 to rotate reversely, the rotating shaft 79 rotates reversely through a gear to drive the first rotating rod 76 to rotate forward, the first rotating rod 76 rotates forward to drive the left electromagnetic wheel 77 and the right electromagnetic wheel 77 to rotate forward, the left electromagnetic wheel 77 and the right electromagnetic wheel 77 rotate forward to drive the trigger plate 78 to swing downward, the trigger plate 78 swings downward to contact with the sliding frame 72, the trigger plate 78 drives the sliding frame 72 to move downward, the second return spring 73 is compressed, the sliding frame 72 moves downward to drive the pressing plate 74 to move downward through the first pressurizing spring 75, the sliding frame 72 stops moving downward to contact with the glass fiber film, the sliding frame 72 stops moving downward, the trigger plate 78 stops swinging downward, the left electromagnetic wheel 77 and the right electromagnetic wheel 77 rotate forward, when vermiculite slides on the glass fiber film, the sliding frame 72 moves downward to the sliding frame 72, the sliding frame 72 continues to move, and the vermiculite is coated on the glass fiber film, and the suspending liquid, so that the suspending liquid is completely extruded into the suspending liquid. After the glass fiber thermal insulation film is made of glass fiber films, the motor 67 is turned off, the motor 67 stops driving the rotating shaft 79 to rotate reversely through synchronous belt transmission, the first rotating rod 76 stops driving the left electromagnetic wheel 77 and the right electromagnetic wheel 77 to rotate positively, the electromagnetic wheels 77 are turned off, the sliding frame 72 moves upwards to reset and drives the trigger plate 78 to swing upwards to reset due to the action of the second reset spring 73, the sliding frame 72 resets and enables the first pressurizing spring 75 to stretch and reset, and the sliding frame 72 drives the pressing plate 74 to move upwards to reset through the first pressurizing spring 75.

Example 2

On the basis of embodiment 1, the cleaning device further comprises a cleaning mechanism 8, the cleaning mechanism 8 comprises a second rotating rod 81, a guide disc 82, a fixing frame 83, a sponge plate 84 and a guide rod 85, please refer to fig. 1, fig. 2, fig. 8 and fig. 9, the fixing frame 83 is fixedly connected to the rear side of the top of the mounting plate 1, the sponge plate 84 is slidably connected to the fixing frame 83, when the sponge plate 84 moves left and right, the sponge plate 84 can remove impurities on the glass fiber membrane, the guide rods 85 are fixedly connected to the lower portions of the left and right sides of the outer side of the sponge plate 84, the second rotating rod 81 is rotatably connected to the rear side of the bottom of the mounting plate 1, the guide discs 82 are fixedly sleeved on the left and right sides of the second rotating rod 81, the guide discs 82 on the left and right sides are respectively in contact with the outer ends of the guide rods 85 on the left and right sides, when the guide discs 82 rotate, the guide discs 82 can drive the guide rods 85 to move left and right, and the right ends of the second rotating rod 81 and an output shaft of the motor 67 are in synchronous belt transmission.

The glass fiber film guiding and positioning device further comprises a material clamping mechanism 9, wherein the material clamping mechanism 9 comprises a mounting seat 91, rubber wheels 92, sliding blocks 93 and second pressurizing springs 94, please refer to fig. 1, fig. 2, fig. 10 and fig. 11, the mounting seat 91 is mounted on the rear side of the top of the mounting plate 1 in a welding connection mode, the mounting seat 91 is located on the rear side of the fixing frame 83, the sliding blocks 93 are connected to the left side and the right side of the mounting seat 91 in a sliding mode, the second pressurizing springs 94 are connected between the tops of the sliding blocks 93 on the left side and the right side and the inner side of the mounting seat 91, the rubber wheels 92 are connected to the inner side faces of the sliding blocks 93 on the left side and the inner side of the mounting seat 91 in a rotating mode, the rubber wheels 92 are connected to the lower portions of the left side and the right side of the mounting seat 91 in a rotating mode, and the rubber wheels 92 can guide and position limiting on a glass fiber film.

After the glass fiber membrane is placed, firstly, the head end of the glass fiber membrane is pulled to penetrate through the sponge plate 84, then, the glass fiber membrane penetrates through the coating component 4 and the drying component 5 to be fixed on the winding drum, the motor 67 is started, the motor 67 drives the second rotating rod 81 to rotate reversely through synchronous belt transmission, the second rotating rod 81 rotates reversely to drive the left and right guide discs 82 to rotate reversely, the left and right guide discs 82 rotate reversely to drive the left and right guide rods 85 to move left and right, the left and right guide rods 85 move left and right to drive the sponge plate 84 to move left and right, the sponge plate 84 moves left and right to remove impurities on the glass fiber membrane, and the wave fiber membrane after the impurities are removed moves forward to be coated with vermiculite suspension to form a heat insulation layer. When motor 67 closed, motor 67 stopped to drive the reversal of second bull stick 81 through synchronous belt drive, and second bull stick 81 stops to drive the left and right sides guide disc 82 reversal, and sponge board 84 just also stops to remove about, so, has impurity influence coating on preventing the glass fiber membrane, has guaranteed the coating quality of glass fiber membrane.

When the glass fiber membrane passes through the sponge plate 84, the glass fiber membrane passes between the rubber wheels 92 on the upper side and the lower side, and due to the action of the second pressurizing spring 94, the rubber wheels 92 on the upper side can be in tight contact with the glass fiber membrane, so that when the glass fiber membrane moves forwards for coating, the rubber wheels 92 on the upper side and the lower side can enable the glass fiber membrane to be coated in a tight state, and therefore the loose phenomenon of the glass fiber membrane is prevented, and the glass fiber membrane can be uniformly coated.

Example 3

On the basis of embodiment 1 and embodiment 2, the pressure adjusting device further includes a pressure adjusting mechanism 10, the pressure adjusting mechanism 10 includes a threaded cylinder 101, a threaded turntable 102, and a limiting plate 103, please refer to fig. 1, fig. 2, and fig. 12, the threaded cylinders 101 are fixedly connected to the lower portions of the left and right sides of the sliding frame 72, the threaded turntables 102 are rotatably connected to the threaded cylinders 101 of the left and right sides in a threaded manner, the limiting plates 103 are fixedly connected to the lower portions of the left and right sides in the supporting frame 71, the limiting plates 103 correspond to the threaded turntable 102, and the limiting plates 103 can limit the threaded turntable 102.

The drying device further comprises a guide mechanism 11, wherein the guide mechanism 11 comprises a hinged frame 111 and guide wheels 112, as shown in fig. 1 and 13, two hinged frames 111 are fixedly connected to the front side and the rear side of the lower portion of the left side surface and the rear side surface of the drying component 5, the guide wheels 112 are rotatably sleeved in the middle of all the hinged frames 111, and the guide wheels 112 can guide the glass fiber heat-insulating film.

The glass fiber heat insulation film scraping device further comprises scraping plates 12, as shown in fig. 1, the scraping plates 12 are fixedly connected to the front side of the bottom in the supporting frame 71 in a bilateral symmetry mode, and the scraping plates 12 can scrape redundant vermiculite suspensions on two sides of the glass fiber heat insulation film.

When the force for extruding the vermiculite suspension needs to be adjusted, the left and right threaded turnplates 102 can be twisted to rotate in a positive and negative alternating mode, the left and right threaded turnplates 102 rotate in a positive and negative alternating mode and move up and down through the threaded cylinders 101, when the left and right threaded turnplates 102 move up and down to proper positions, the left and right threaded turnplates 102 stop being twisted to rotate in a positive and negative alternating mode, when the sliding frame 72 moves downwards, the sliding frame 72 also drives the left and right threaded cylinders 101 to move downwards, the left and right threaded cylinders 101 move downwards to drive the left and right threaded turnplates 102 to move downwards, when the left and right threaded turnplates 102 move downwards to contact with the left and right limiting plates 103, the left and right limiting plates 103 limit the left and right threaded turnplates 102, and the sliding frame 72 also stops moving downwards. When carriage 72 upwards removes and resets, carriage 72 drives left and right sides screw thread carousel 102 rebound through left and right sides screw thread section of thick bamboo 101 and resets, and left and right sides screw thread carousel 102 resets and breaks away from the contact with left and right sides limiting plate 103, so, can adjust the dynamics of extrusion vermiculite suspension as required, just also can carry out the accuse to coating quality.

When the glass fiber membrane passed drying assembly 5, glass fiber membrane and leading wheel 112 contact, and leading wheel 112 leads the glass fiber membrane of removal, so, prevent that the glass fiber membrane from hugging closely drying assembly 5, guarantee that the glass fiber membrane can not scalded.

When the glass fiber membrane moves forwards, the scraper 12 can scrape off the redundant vermiculite suspension on the two sides of the glass fiber membrane, so that the redundant vermiculite suspension is prevented from remaining on the two sides to influence the quality, and the quality of the glass fiber heat insulation membrane is further ensured.

Finally, it is necessary to mention that: the above-mentioned contents are only used to help understanding the technical solution of the present invention, and should not be interpreted as limiting the scope of the present invention; insubstantial modifications and adaptations of the invention as described above will occur to those skilled in the art and are intended to be within the scope of the invention as claimed.

Claims (8)

1. The utility model provides a production of glass fiber thermal-insulated membrane is with insulating layer coating machine, including mounting panel (1), landing leg (2), u type seat (3), coating subassembly (4) and stoving subassembly (5), mounting panel (1) bottom rigid coupling has landing leg (2), mounting panel (1) trailing flank bilateral symmetry rigid coupling has u type seat (3) that are used for the glass fiber membrane to carry out to place, rigid coupling has coating subassembly (4) in the middle of mounting panel (1) top, rigid coupling has stoving subassembly (5) in the middle of mounting panel (1) top front side, the novel glass fiber membrane coating machine is characterized by, still including winding mechanism (6) and pressure and neatening mechanism (7), be provided with winding mechanism (6) that are used for driving the glass fiber membrane and move forward coated on mounting panel (1), be provided with between mounting panel (1) and winding mechanism (6) and be used for compressing vermiculite suspension hydraulic pressure to the interior pressure of glass fiber membrane (7).

2. The heat insulation layer coating machine for producing the glass fiber heat insulation film as claimed in claim 1, wherein the winding mechanism (6) comprises a fixed seat (61), a sliding seat (62), a first return spring (63), a discharging shaft (64), a hexagonal rod (65) and a motor (67), the fixed seat (61) is fixedly connected to the front side of the mounting plate (1), the sliding seat (62) is slidably connected to the left side of the inner rear side of the fixed seat (61), the discharging shaft (64) for placing the winding drum is detachably installed between the sliding seat (62) and the right side of the fixed seat (61) in a rotating manner, the hexagonal grooves are formed in the left end and the right end of the discharging shaft (64), the first return spring (63) is connected between the right side of the sliding seat (62) and the inner side of the fixed seat (61), the hexagonal rod (65) for driving the discharging shaft (64) to rotate is connected to the right side of the fixed seat (61) in a penetrating manner, the left end of the hexagonal rod (65) is positioned in the hexagonal groove in the right side of the discharging shaft (64), the motor (67) is fixedly connected to the right front side of the bottom of the mounting plate (1), and a synchronous belt transmission is connected between the hexagonal rod (65) and an output shaft.

3. The heat-insulating layer coating machine for producing the glass fiber heat-insulating film is characterized in that the pressing mechanism (7) comprises a support frame (71), a sliding frame (72), a second reset spring (73), a pressing plate (74), a first pressurizing spring (75), a first rotating rod (76), an electromagnetic wheel (77), a trigger plate (78) and a rotating shaft (79), the support frame (71) is fixedly connected to the front side of the top of the mounting plate (1), the sliding frame (72) is connected to the rear part of the support frame (71) in a sliding mode in a penetrating mode, the second reset spring (73) is connected between the left side and the right side of the inner top of the sliding frame (72) and the left side and the right side of the rear part of the support frame (71) respectively, a pressing plate (74) used for extruding vermiculite suspension is connected at the bottom of the sliding frame (72) in a sliding mode in a penetrating mode, first pressurizing springs (75) are symmetrically connected between the inner bottom of the pressing plate (74) and the outer bottom of the sliding frame (72) in a left-right mode, a first rotating rod (76) is connected in a penetrating mode in a front rotating mode of the supporting frame (71), electromagnetic wheels (77) are fixedly connected in the left-right mode in the middle of the first rotating rod (76) in a left-right mode, a trigger plate (78) used for driving the sliding frame (72) to move downwards is sleeved in the rotating mode in the middle of the first rotating rod (76), the trigger plate (78) is in magnetic contact with the electromagnetic wheels (77) on the left side and the right side, a rotating shaft (79) is connected in a front-side rotating mode on the outer right side of the supporting frame (71), the right side of the rotating shaft (79) and the output shaft of the motor (67) are in synchronous belt transmission, and the middle of the rotating shaft (79) and the right side of the first rotating rod (76) are in gear transmission.

4. The heat insulation layer coating machine for producing the glass fiber heat insulation film according to claim 3, characterized by further comprising a cleaning mechanism (8) for removing impurities on the glass fiber film, wherein the cleaning mechanism (8) comprises a second rotating rod (81), a guide disc (82), a fixing frame (83), a sponge plate (84) and guide rods (85), the fixing frame (83) is fixedly connected to the rear side of the top of the mounting plate (1), the sponge plate (84) for removing the impurities on the glass fiber film is slidably connected to the fixing frame (83), the guide rods (85) are fixedly connected to the lower portions of the left side and the right side of the outer side of the sponge plate (84), the second rotating rod (81) is rotatably connected to the rear side of the bottom of the mounting plate (1), guide discs (82) for driving the guide rods (85) to move left and right are fixedly sleeved on the left and right sides of the second rotating rod (81), the guide discs (82) on the left and right sides are respectively contacted with the guide rods (85), and the right end of the second rotating rod (81) is in transmission with an output shaft of the motor (67).

5. The heat insulation layer coating machine for producing the glass fiber heat insulation film according to claim 4, characterized by further comprising a clamping mechanism (9) for tightening the glass fiber film, wherein the clamping mechanism (9) comprises a mounting seat (91), rubber wheels (92), sliding blocks (93) and second pressurizing springs (94), the mounting seat (91) is fixedly connected to the rear side of the top of the mounting plate (1), the mounting seat (91) is located on the rear side of the fixing frame (83), the sliding blocks (93) are connected to the left side and the right side of the mounting seat (91) in a sliding manner, the second pressurizing springs (94) are connected between the tops of the sliding blocks (93) on the left side and the right side and the inner side of the mounting seat (91), the rubber wheels (92) for guiding and limiting the glass fiber film are connected to the inner side surfaces of the sliding blocks (93) on the left side and the right side in the mounting seat (91) in a rotating manner, and the lower portions of the left side and the right side in the mounting seat (91) are also connected to the rubber wheels (92) in a rotating manner.

6. The thermal insulation layer coating machine for producing the glass fiber thermal insulation film according to claim 5, characterized by further comprising a pressure adjusting mechanism (10) for adjusting the extrusion force, wherein the pressure adjusting mechanism (10) comprises a threaded cylinder (101), a threaded turntable (102) and a limiting plate (103), the threaded cylinder (101) is fixedly connected to the lower portions of the left side and the right side of the sliding frame (72), the threaded turntable (102) is connected to the threaded cylinder (101) on the left side and the right side in a threaded manner in a rotating manner, the limiting plate (103) for limiting the threaded turntable (102) is fixedly connected to the lower portions of the left side and the right side in the supporting frame (71), and the limiting plate (103) corresponds to the threaded turntable (102).

7. The heat-insulating layer coating machine for producing the glass fiber heat-insulating film is characterized by further comprising a guide mechanism (11) for guiding the glass fiber heat-insulating film, wherein the guide mechanism (11) comprises a hinged frame (111) and guide wheels (112), the front side and the rear side of the lower part of the left side surface and the right side surface of the drying component (5) are fixedly connected with the two hinged frames (111), and the guide wheels (112) for guiding the glass fiber heat-insulating film are rotatably sleeved in the middles of all the hinged frames (111).

8. The heat-insulating layer coating machine for producing the glass fiber heat-insulating film according to claim 7, characterized by further comprising scraping plates (12), wherein the scraping plates (12) for scraping the redundant vermiculite suspension on the two sides of the glass fiber heat-insulating film are fixedly connected to the front side of the bottom in the supporting frame (71) in a left-right symmetrical manner.

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