CN220665819U - Automatic shaping hot press - Google Patents

Abstract

The utility model provides an automatic forming hot press, which relates to the technical field of hot press forming and comprises a frame, wherein a forming mechanism, a wringing mechanism, a material moving mechanism, an oil station and a pulp barrel are arranged on the frame; the molding mechanism comprises a molding die and a molding power mechanism; the wringing mechanism comprises a wringing mould and a wringing power mechanism; the material moving mechanism comprises a material moving platform and a material moving power mechanism, and the material moving platform is positioned above the forming die and the wringing die. The utility model has the advantages that when in operation, the slurry is dehydrated and molded by the molding die to obtain a product initially, then the product is moved to the wringing die from the material moving platform, the wringing die wrings out the residual moisture in the product, and finally the material is received. Namely, after the hot press forming is finished, the product is squeezed to be shaped, the actions of the front working procedure and the back working procedure are consistent, the obtained product is firm in forming and reliable in quality, the working procedure interval is not needed to be manually intervened, and the structure is ingenious.

Description

Automatic shaping hot press

Technical Field

The utility model relates to the technical field of hot press forming, in particular to an automatic forming hot press.

Background

The hot press molding machine has been widely used, and molded articles using rubber, plastic, pulp and the like as raw materials in daily life are required to be utilized.

The technical contents disclosed in the Chinese patent document (application number: CN202221101759.5, patent name: an extrusion molding device for paper molded products) include: the lower frame (2) is installed to the below of going up frame (1), the one end of lower frame (2) bottom is provided with paper pulp pond (4), paper pulp pond (4) top is provided with upset subassembly (3) that can overturn and paper pulp contacted, it is provided with lifting unit (5) that can go up to upset subassembly (3) to go up frame (1) top, it has hot press die (7) to go up frame (1) bottom swing joint, the both sides of hot press die (7) all are provided with connecting plate (14), one of them the opposite side of connecting plate (14) is provided with cold extrusion die (6), another the opposite side of hot press die (7) is provided with gets material die (11).

From the above, the extrusion molding device only performs hot press molding treatment on the product, so that more water still exists in the product, and in actual production, the subsequent water extrusion treatment must be performed on the molded product, otherwise, the product is not firmly molded, and the quality and yield of the product are affected. If the device can only carry out hot press molding on the product without subsequent water squeezing, the working procedure of manually receiving materials and feeding materials to the water squeezing device is added, the process depends on manual work and increases time cost, and the device is very inconvenient.

Disclosure of Invention

The utility model overcomes the defects in the prior art, and provides an automatic forming hot press which can overcome the defects in the prior art mentioned in the background art.

In order to solve the technical problems, the utility model is realized by the following technical scheme:

an automatic forming hot press comprises a frame, wherein a forming mechanism, a wringing mechanism, a material moving mechanism, a frame, an oil station and a pulp barrel are arranged on the frame, and the pulp barrel is arranged below the forming mechanism; the molding mechanism comprises a molding die and a molding power mechanism; the wringing mechanism comprises a wringing mould and a wringing power mechanism; the material moving mechanism comprises a material moving platform and a material moving power mechanism, and the material moving platform is positioned above the forming die and the wringing die.

Still further, be provided with first material subassembly and the second material subassembly that moves on the material platform that moves, first material subassembly that moves install in the forming die top, the second material subassembly that moves install in the wringing mold top, both synchronous actions.

Further, a first vacuum air blowing port is arranged on the surface, which is contacted with the forming die, of the first material moving component, and a second vacuum air blowing port is arranged on the surface, which is contacted with the first material moving component, of the forming die.

Further, a third vacuum air blowing port is arranged on the surface, which is contacted with the water squeezing die, of the second material shifting component, and a fourth vacuum air blowing port is arranged on the surface, which is contacted with the second material shifting component, of the water squeezing die.

Further, the surface of the first material moving component, which is contacted with the forming die, is a first heating surface, and the surface of the second material moving component, which is contacted with the water squeezing die, is a second heating surface.

Further, the surface of the water squeezing die, which is contacted with the second material moving component, is a third heating surface;

further, the first material moving component comprises a first heating component, the second material moving component comprises a second heating component, the wringing mechanism comprises a third heating component, and the first heating component, the second heating component and the third heating component are heating pipes;

still further, the thick liquid bucket is equipped with the back pulp groove, and the back pulp groove connects back pulp flange interface, and when thick liquid in the thick liquid bucket reached certain height, unnecessary thick liquid flowed back the thick liquid pond through back pulp flange interface.

Compared with the prior art, the utility model has the beneficial effects that:

the material moving mechanism comprises a material moving platform and a material moving power mechanism, wherein the material moving platform is positioned above a forming die and a water squeezing die, when the material moving mechanism works, slurry is dehydrated and formed through the forming die to initially obtain a product, then the forming power mechanism enables the forming die to be attached to the material moving platform, the material moving power mechanism drives the material moving platform to move the product to the water squeezing die, then the water squeezing power mechanism enables the water squeezing die to be attached to the material moving platform, residual moisture in the product is squeezed out, and finally material collection is carried out. The hot press forming process has the advantages that after the hot press forming is finished, the product is immediately squeezed, the actions of the front working procedure and the back working procedure are consistent, the obtained product is firm in forming and reliable in quality, meanwhile, the labor cost and the production time are saved, the manual intervention is not needed in the middle, the working procedure interval is greatly shortened, and the structure is ingenious.

Drawings

The accompanying drawings are included to provide a further understanding of the utility model, and are incorporated in and constitute a part of this specification, in which:

FIG. 1 is a front view of an embodiment of the present utility model;

FIG. 2 is a schematic diagram of an embodiment of the present utility model;

FIG. 3 is a schematic structural view of a molding mechanism;

FIG. 4 is a schematic diagram of a material moving power mechanism;

FIG. 5 is a schematic structural view of a wringing mechanism;

FIG. 6 is a schematic view of the installation of the first and second transfer assemblies on the transfer mechanism;

fig. 7 is a schematic structural view of a pulp return tank of the pulp barrel.

In the figure: 1. a frame; 2. a forming mechanism; 201. a forming die; 202. forming a power mechanism; 203. a second vacuum air-blowing port; 3. a wringing mechanism; 301. a water squeezing die; 302. a water squeezing power mechanism; 303. a fourth vacuum air-blowing port; 304. a third heating surface; 305. a third heat generating component; 4. a material moving mechanism; 401. a material moving platform; 402. a material moving power mechanism; 402A, a motor; 402B, a coupling; 402C, a screw rod; 402D, a lead screw nut; 5. a first material moving assembly; 501. a first vacuum air-blowing port; 502. a first heating surface; 503. a first heating assembly; 6. a second material moving assembly; 601. a third vacuum air-blowing port; 602. a second heating surface; 603. a second heat generating component; 7. an oil station; 8. a pulp barrel; 801. a slurry return groove; 802. and (5) a back sizing flange interface.

Detailed Description

The preferred embodiments of the present utility model will be described below with reference to the accompanying drawings, it being understood that the preferred embodiments described herein are for illustration and explanation of the present utility model only, and are not intended to limit the present utility model.

As shown in fig. 1 to 6, an automatic forming hot press comprises a frame 1, wherein a forming mechanism 2 and a wringing mechanism 3 are arranged on the frame, and a material moving mechanism 4 is positioned above the forming mechanism 2 and the wringing mechanism 3; the material moving mechanism is provided with a first material moving component 5 and a second material moving component 6, and the pulp barrel 8 is arranged below the forming mechanism 2.

As shown in fig. 3, the molding mechanism 2 includes a molding die 201, a molding power mechanism 202, and a second vacuum air blowing port 203. Wherein the forming die 201 is used for accommodating slurry, the product is obtained primarily after dehydration, and the forming power mechanism 202 is an air cylinder. When the device works, the air inlet of the air cylinder is filled, the air cylinder rod stretches out to drive the forming die 201 to move downwards to the pulp barrel 8 for pulp filling, then the air cylinder is changed into the air outlet for air filling, the air cylinder rod starts to retract to drive the forming die 201 to move upwards for dehydration forming, finally the air cylinder drives the lower forming die 201 to move upwards to be attached to the first material moving assembly 5, the first vacuum air blowing port 501 on the first material moving assembly 5 is used for vacuum suction, the second vacuum air blowing port 203 is used for blowing air, and a product is adsorbed by the first heating surface 502 of the first material moving assembly 5, so that the product is moved to the wringing mechanism 3 for wringing shaping through the first material moving assembly 5. The first heating component 503 is a heating tube, and is used for heating the first heating surface 502, thereby heating the product to improve the molding quality thereof.

As shown in fig. 4, the material moving power mechanism 402 includes a motor 402A, the motor 402A is connected with a screw rod 402C through a coupling 402B, a screw rod nut 402D is connected to the screw rod 402C in a matching manner, the screw rod nut 402D is connected to the material moving platform 401, and when the motor 402A works, the screw rod 402C is driven to rotate, and finally the material moving platform 401 is driven to move, so that a product on the first material moving assembly 5 is moved above the water squeezing die 301.

As shown in fig. 5, the wringing power mechanism 302 is an oil cylinder, when oil is fed into the cavity of the oil cylinder, an upward thrust is provided, the wringing mold 301 is driven to move upwards to be attached to the first material moving component 5, then the first vacuum air blowing port 501 blows air, the fourth vacuum air blowing port 303 on the wringing mechanism 3 vacuum-sucks air, so that a product is adsorbed by the third heating surface 304 on the wringing mechanism 3 to prepare for subsequent wringing, wherein the third heating surface 304 is heated by the third heating component 305, and the third heating component 305 is a heating tube, and can play a role in drying the product in the wringing process.

Then oil is drained from the oil cylinder cavity, the wringing power mechanism 302 drives the wringing mould to move downwards, then the material moving power mechanism 402 drives the material moving platform 401 to reset, at this time, the wringing power mechanism 302 drives the wringing mould 301 to move upwards to be attached to the second material moving assembly 6, residual moisture in the product is squeezed out, and the forming quality of the product is improved. Then the fourth vacuum air blowing port 303 blows air, and the third vacuum air blowing port 601 on the second material moving component 6 vacuum sucks air, so that the product is adsorbed by the second heating surface 602 on the second material moving component 6, and preparation is made for receiving the subsequent product. The second heating surface 602 is heated by the second heating component 603, and the second heating component 603 is a heating tube, which can dry the product in the process of squeezing water.

As shown in fig. 6, the material moving power mechanism 402 synchronously drives the first material moving component 5 and the second material moving component 6 to act, and when the first material moving component 5 sends the product to the wringing mold 301 for wringing, the last product with wringing is sent to the material receiving position by the second material moving component 6, so that in the working process, the forming and wringing shaping processes synchronously work, the product does not need to be subjected to wringing treatment, and the production efficiency is effectively improved.

As shown in fig. 7, the slurry barrel 8 comprises a barrel body 801, wherein a slurry return groove 802 is arranged in the barrel body 801, when the liquid level of slurry in the barrel body 801 exceeds the slurry return groove 802, excessive slurry flows into the slurry return groove 802, and redundant slurry is conveyed back to a slurry tank by a slurry return flange interface 803, so that the slurry can be continuously supplied to the barrel body 801 in the working process, and the slurry in the barrel body 801 is ensured to be sufficient all the time and not overflow. The drain 804 is used for discharging redundant waste liquid, the slurry supply flange interface 805 is used for conveying slurry into the barrel body, and the vacuum connector 806 is used for sucking redundant slurry in the barrel body.

Finally, it should be noted that: although the present utility model has been described in detail with reference to the embodiments, it should be understood that the utility model is not limited to the preferred embodiments, but is capable of modification and equivalents to some of the features described in the foregoing embodiments, but is intended to cover all modifications, equivalents, and alternatives falling within the spirit and principles of the utility model.

Claims (8)

1. The automatic forming hot press is characterized by comprising a frame, wherein a forming mechanism, a wringing mechanism, a material moving mechanism, an oil station and a pulp barrel are arranged on the frame, and the pulp barrel is arranged below the forming mechanism; the molding mechanism comprises a molding die and a molding power mechanism; the wringing mechanism comprises a wringing mould and a wringing power mechanism; the material moving mechanism comprises a material moving platform and a material moving power mechanism, and the material moving platform is positioned above the forming die and the wringing die.

2. The automatic forming hot press according to claim 1, wherein the material moving platform is provided with a first material moving component and a second material moving component, the first material moving component is installed above the forming die, and the second material moving component is installed above the wringing die, and the first material moving component and the second material moving component synchronously act.

3. The automated molding press of claim 2, wherein the first material transfer module has a first vacuum port on a surface thereof contacting the molding die, and wherein the molding die has a second vacuum port on a surface thereof contacting the first material transfer module.

4. The automated molding press of claim 2, wherein the second material transfer module has a third vacuum port on a surface thereof contacting the wringing mold and a fourth vacuum port on a surface thereof contacting the second material transfer module.

5. The automated molding press of claim 2, wherein the surface of the first material transfer assembly that contacts the molding die is a first heating surface and the surface of the second material transfer assembly that contacts the wringing die is a second heating surface.

6. The automated forming press of claim 5, wherein the surface of the wringing die that contacts the second material-moving component is a third heating surface.

7. The automated molding press of claim 6, wherein the first material moving assembly comprises a first heating assembly, the second material moving assembly comprises a second heating assembly, the wringing mechanism comprises a third heating assembly, and the first heating assembly, the second heating assembly, and the third heating assembly are heating tubes.

8. An automatic forming hot press according to claim 1, wherein the vat is provided with a return vat, the return vat being connected to a return flange interface, through which excess slurry flows back to the vat when the slurry in the vat reaches a certain level.