CN219505434U

CN219505434U - Thermal insulation tectorial membrane shaping coining mill

Info

Publication number: CN219505434U
Application number: CN202320812541.9U
Authority: CN
Inventors: 金博哲; 祝艳艳
Original assignee: Dongguan Purehill Material Technology Co ltd
Current assignee: Dongguan Purehill Material Technology Co ltd
Priority date: 2023-04-13
Filing date: 2023-04-13
Publication date: 2023-08-11
Anticipated expiration: 2033-04-13

Abstract

The utility model discloses a heat-insulating laminating molding embossing machine, which relates to the technical field of laminating equipment, and comprises a frame, a first driving mechanism, an unreeling component, a laminating component, a preheating mechanism, a second driving mechanism, an embossing component, a slitting component and a reeling component, wherein the unreeling component, the laminating component, the preheating mechanism, the embossing component, the slitting component and the reeling component are sequentially arranged on the frame, the first driving mechanism drives the laminating component to work, and the second driving mechanism drives the embossing component, the slitting component and the reeling component to work at the same time; the utility model realizes the secondary heating softening of the laminated film material, and further improves the cold press shaping effect of the laminated film material.

Description

Thermal insulation tectorial membrane shaping coining mill

Technical Field

The utility model relates to the technical field of laminating equipment, in particular to a heat-preservation laminating forming embossing machine.

Background

The laminating equipment is a machine for bonding different plastic films together through a high-temperature hot laminating composite process and then cold-pressing and molding the surfaces of the materials, and the traditional laminating equipment uses the waste heat of the laminating materials to immediately perform cold-pressing and shaping after being commonly laminated through a laminating hot roller; the film-covered material needs to be soft enough when cold pressing, so that the film-covered material has a good cold pressing shaping effect; however, the laminating material does not need to be softened enough when being laminated, so the temperature requirement during lamination is lower than the temperature required during cold pressing, in addition, heat is dissipated when the laminating material moves from a hot roller to cold pressing equipment, the temperature of the laminating material during cold pressing is insufficient, the material is not flexible enough, and the cold pressing effect is directly affected.

Disclosure of Invention

The utility model aims to realize secondary heating softening of the laminated film material and further improve the cold press shaping effect of the laminated film material.

In order to achieve the above purpose, the technical scheme adopted by the utility model is as follows:

the utility model provides a heat preservation tectorial membrane shaping coining mill, includes the frame, still includes first actuating mechanism, unreels the subassembly, laminating subassembly, preheats mechanism, second actuating mechanism, knurling subassembly, cuts subassembly and rolling subassembly, unreel subassembly, laminating subassembly, preheats mechanism, knurling subassembly, cut subassembly and rolling subassembly and set gradually in the frame, first actuating mechanism drives laminating subassembly work, second actuating mechanism drives knurling subassembly, cuts subassembly and rolling subassembly work simultaneously.

Further, unreeling assembly includes unreeling roller, guide frame, tension roller, unreeling roller, guide frame, tension roller all pin joint in the frame, guide frame is located unreeling roller's below, tension roller is located unreeling roller and laminating subassembly between.

Further, the unreeling assembly further comprises a wide-width balance rubber roller, wherein the wide-width balance rubber roller is pivoted on the frame and is positioned between the tension roller and the attaching assembly.

Further, the laminating subassembly includes tectorial membrane hot roll, tectorial membrane rubber roll, tectorial membrane hot roll and tectorial membrane rubber roll pin joint are in the frame, and tectorial membrane hot roll offsets with the lateral surface of tectorial membrane rubber roll, first actuating mechanism drive tectorial membrane hot roll rotates.

Further, the embossing assembly comprises a water-cooling embossing roller and an auxiliary rubber roller, wherein the water-cooling embossing roller and the auxiliary rubber roller are both pivoted on the frame, the outer side surfaces of the water-cooling embossing roller and the auxiliary rubber roller are propped against each other, and the second driving mechanism drives the water-cooling embossing roller to rotate.

Further, the lifting frame also comprises a lifting frame, wherein the lower end of the lifting frame is pivoted at the side edge of the frame.

Further, the slitting assembly comprises a driving roller and two groups of cutters, the two groups of cutters are symmetrically and fixedly arranged on the driving roller, the driving roller is pivoted on the frame, and the second driving mechanism drives the driving roller to rotate.

Further, the winding assembly comprises a driving winding roller and a driven winding roller, the driving winding roller and the driven winding roller are both pivoted on the frame, the outer side surfaces of the driving winding roller and the driven winding roller are propped against each other, and the second driving mechanism drives the driving winding roller to rotate.

The beneficial effects of the utility model are as follows: according to the utility model, the laminating material sequentially passes through the unreeling component, the laminating component, the preheating mechanism, the embossing component, the slitting component and the reeling component, the laminating component pulls the laminating material to move when the first driving mechanism drives the laminating component to work, the laminating material is heated and laminated at the same time, the laminating material is heated for the second time through the preheating mechanism when passing through the preheating mechanism, then cold-pressed through the embossing component, the laminating material after cold-pressing is slit in a wide range through the slitting component, and finally the reeling component is used for reeling; as the preheating mechanism heats the laminating material for the second time, the laminating material reaches the temperature required during shaping, and the laminating material is further softened, so that the embossing assembly is more beneficial to shaping the laminating material.

Drawings

FIG. 1 is a schematic view of the overall structure of the present utility model;

the reference numerals are:

the machine frame 1, a first driving mechanism 2, an unreeling component 3, an unreeling roller 31, a material guiding frame 32, a tension roller 33, a wide-width balance rubber roller 34,

Laminating subassembly 4, tectorial membrane hot roll 41, tectorial membrane rubber roll 42, preheating mechanism 5, second actuating mechanism 6, knurling subassembly 7, water-cooling knurling roller 71, supplementary rubber roll 72, slitting subassembly 8, drive roller 81, two sets of cutters 82, winding subassembly 9, initiative wind-up roll 91, driven wind-up roll 92, hoisting frame 10.

Detailed Description

The utility model is further described below with reference to the accompanying drawings.

The heat-preservation tectorial membrane shaping embossing machine as shown in fig. 1 comprises a frame 1, a first driving mechanism 2, an unreeling component 3, a laminating component 4, a preheating mechanism 5, a second driving mechanism 6, an embossing component 7, a slitting component 8, a reeling component 9 and a hoisting frame 10.

The unreeling assembly 3, the laminating assembly 4, the preheating mechanism 5, the embossing assembly 7, the slitting assembly 8 and the reeling assembly 9 are sequentially arranged on the frame 1, the first driving mechanism 2 drives the laminating assembly 4 to work, and the second driving mechanism 6 simultaneously drives the embossing assembly 7, the slitting assembly 8 and the reeling assembly 9 to work; the laminating material passes unreeling subassembly 3, laminating subassembly 4, preheating mechanism 5, knurling subassembly 7, cut subassembly 8, rolling subassembly 9 in proper order to unreel through unreeling subassembly 3 respectively, laminating subassembly 4 heats laminating, preheating mechanism 5 heats secondarily, knurling subassembly 7 cold-presses, cuts the broad width of laminating subassembly 8, and rolling subassembly 9 rolls.

The unreeling component 3 comprises an unreeling roller 31, a material guiding frame 32, a tension roller 33 and a wide-width balance rubber roller 34, wherein the unreeling roller 31, the material guiding frame 32, the tension roller 33 and the wide-width balance rubber roller 34 are all pivoted on the frame 1, the material guiding frame 32 is positioned below the unreeling roller 31, the tension roller 33 is positioned between the unreeling roller 31 and the attaching component 4, the wide-width balance rubber roller 34 is positioned between the tension roller 33 and the attaching component 4, that is to say, the unreeling roller 31, the tension roller 33, the wide-width balance rubber roller 34 and the attaching component 4 are sequentially arranged; the coiled film material is set up by the unreeling roller 31, one end of the film material is wound on the material guiding frame 32, the tension roller 33 and the wide-width balance rubber roller 34 in sequence, the film material is guided out by the material guiding frame 32, the tension of the film material is adjusted by the tension roller 33, and the balance adjustment is carried out on the two sides of the film material by the wide-width balance rubber roller 34.

The laminating assembly 4 comprises a film laminating hot roller 41 and a film laminating rubber roller 42, wherein the film laminating hot roller 41 and the film laminating rubber roller 42 are pivoted on the frame 1, the film laminating hot roller 41 is abutted against the outer side surface of the film laminating rubber roller 42, and the first driving mechanism 2 drives the film laminating hot roller 41 to rotate; one end of the film material passes through the space between the film heat roller 41 and the film laminating rubber roller 42, the film material is heated by the film heat roller 41, and the film material is bonded under the mutual extrusion action of the film heat roller 41 and the film laminating rubber roller 42.

When the laminating material passes through the preheating mechanism 5, the laminating material is heated for the second time through the preheating mechanism 5, so that the laminating material reaches the temperature required during shaping, and the laminating material is further softened, so that the laminating material is more beneficial to shaping of the embossing assembly 7, and the shaping quality and the cold pressing effect are further improved.

The embossing assembly 7 comprises a water-cooling embossing roller 71 and an auxiliary rubber roller 72, the water-cooling embossing roller 71 and the auxiliary rubber roller 72 are pivoted on the frame 1, the outer side surfaces of the water-cooling embossing roller 71 and the auxiliary rubber roller 72 are propped against each other, and the second driving mechanism 6 drives the water-cooling embossing roller 71 to rotate; one end of the film-covered material passes through between the water-cooled embossing roller 71 and the auxiliary rubber roller 72, and cold-presses the film-covered material under the mutual extrusion action of the water-cooled embossing roller 71 and the auxiliary rubber roller 72.

The lower extreme pin joint of hoisting frame 10 is in the side of frame 1, and hoisting frame 10 wholly can be rotatory three hundred sixty degrees along pin joint department, and hoisting frame 10's effect lies in: when the water-cooled embossing roll 71 needs to be replaced, the water-cooled embossing roll 71 can be lifted up with the aid of the crane boom 10 and then rotated along the pivot, so that the water-cooled embossing roll 71 is transferred and sent out.

The slitting assembly 8 comprises a driving roller 81 and two groups of cutters 82, the two groups of cutters 82 are symmetrically and fixedly arranged on the driving roller 81, the driving roller 81 is pivoted on the frame 1, the second driving mechanism 6 drives the driving roller 81 to rotate, and then the two groups of cutters 82 are driven to rotate, and the two sides of the film coating material passing through the driving roller 81 are slit, so that the width reaches the customer requirement.

The winding assembly 9 comprises a driving winding roller 91 and a driven winding roller 92, the driving winding roller 91 and the driven winding roller 92 are both pivoted on the frame 1, the outer side surfaces of the driving winding roller 91 and the driven winding roller 92 are propped against each other, and the second driving mechanism 6 drives the driving winding roller 91 to rotate; one end of the film-coated material passes through the space between the driving winding roller 91 and the driven winding roller 92, and the film-coated material is taken out under the interaction of the driving winding roller 91 and the driven winding roller 92.

The working principle of the utility model is as follows: 1. the coiled film coating material is erected through an unreeling roller 31, one end of the film coating material is sequentially wound on a material guide frame 32, a tension roller 33 and a wide-width balance rubber roller 34, the film coating material is guided open through the material guide frame 32, the tension of the film coating material is adjusted through the tension roller 33, and the balance adjustment is carried out on the two sides of the film coating material through the wide-width balance rubber roller 34;

2. one end of the laminating material passes through the space between the laminating hot roller 41 and the laminating rubber roller 42, the laminating hot roller 41 heats the laminating material, and the laminating hot roller 41 and the laminating rubber roller 42 are mutually extruded to bond the laminating material;

3. the laminating material passes through the preheating mechanism 5, and is heated for the second time through the preheating mechanism 5, so that the laminating material reaches the temperature required by shaping, and is further softened, so that the laminating material is more beneficial to shaping by the embossing assembly 7, and the shaping quality and the cold pressing effect are further improved;

4. one end of the laminating material passes through the space between the water-cooling embossing roller 71 and the auxiliary rubber roller 72, and cold pressing is carried out on the laminating material under the mutual extrusion action of the water-cooling embossing roller 71 and the auxiliary rubber roller 72;

5. the second driving mechanism 6 drives the driving roller 81 to rotate, so as to drive the two groups of cutters 82 to rotate, and the two sides of the film-coated material passing through the driving roller 81 are cut to be wide, so that the wide width meets the requirements of customers;

6. one end of the film-coated material passes through the space between the driving winding roller 91 and the driven winding roller 92, and the film-coated material is taken out under the interaction of the driving winding roller 91 and the driven winding roller 92.

The above disclosure is only a preferred embodiment of the present utility model, and the scope of the present utility model is not limited thereto, so that the present utility model is not limited to the above embodiments, and any modifications, equivalents and modifications made to the above embodiments according to the technical principles of the present utility model are still within the scope of the present utility model.

Claims

1. The utility model provides a heat preservation tectorial membrane shaping coining mill, includes frame, its characterized in that: still include first actuating mechanism, unreel the subassembly, laminating subassembly, preheat the mechanism, second actuating mechanism, knurling subassembly, cut subassembly and rolling subassembly, unreel the subassembly, laminate the subassembly, preheat mechanism, knurling subassembly, cut subassembly and rolling subassembly and set gradually in the frame, first actuating mechanism drives laminating subassembly work, second actuating mechanism drives knurling subassembly, cuts subassembly and rolling subassembly work simultaneously.

2. The thermal insulation film forming embossing machine as set forth in claim 1, wherein: unreeling subassembly includes unreeling roller, guide frame, tension roller, unreeling roller, guide frame, tension roller all pin joint in the frame, guide frame is located unreeling roller's below, tension roller is located between unreeling roller and the laminating subassembly.

3. The thermal insulation film forming embossing machine as set forth in claim 2, wherein: the unreeling assembly further comprises a wide-width balance rubber roller, wherein the wide-width balance rubber roller is pivoted on the frame and is positioned between the tension roller and the attaching assembly.

4. The thermal insulation film forming embossing machine as set forth in claim 1, wherein: the laminating subassembly includes tectorial membrane hot roll, tectorial membrane rubber roll, tectorial membrane hot roll and tectorial membrane rubber roll pin joint are in the frame, and tectorial membrane hot roll offsets with the lateral surface of tectorial membrane rubber roll, first actuating mechanism drive tectorial membrane hot roll rotates.

5. The thermal insulation film forming embossing machine as set forth in claim 1, wherein: the embossing assembly comprises a water-cooling embossing roller and an auxiliary rubber roller, wherein the water-cooling embossing roller and the auxiliary rubber roller are both pivoted on the frame, the outer side surfaces of the water-cooling embossing roller and the auxiliary rubber roller are propped against each other, and the second driving mechanism drives the water-cooling embossing roller to rotate.

6. The thermal insulation film forming embossing machine as set forth in claim 1, wherein: the lifting frame is characterized by further comprising a lifting frame, wherein the lower end of the lifting frame is pivoted to the side edge of the frame.

7. The thermal insulation film forming embossing machine as set forth in claim 1, wherein: the slitting assembly comprises a driving roller and two groups of cutters, the two groups of cutters are symmetrically and fixedly arranged on the driving roller, the driving roller is pivoted on the frame, and the second driving mechanism drives the driving roller to rotate.

8. A thermal insulation film forming embosser as claimed in any one of claims 1 to 7, wherein: the winding assembly comprises a driving winding roller and a driven winding roller, the driving winding roller and the driven winding roller are both pivoted on the frame, the outer side surfaces of the driving winding roller and the driven winding roller are propped against each other, and the second driving mechanism drives the driving winding roller to rotate.