CN221756832U - Annealing and cooling device for hot-pressing die - Google Patents

Abstract

The utility model discloses an annealing and cooling device for hot pressing molds, including a furnace, and several groups of annealing modules and cooling modules that can be embedded in the furnace cavity; the annealing module and the cooling module both include a bottom plate and a pressure plate relatively arranged in the furnace cavity, and the pressure plate is driven by a lifting mechanism and can be close to the surface of the hot pressing mold; the pressure plate and/or the bottom plate on the annealing module can heat the hot pressing mold; the pressure plate and/or the bottom plate on the cooling module are provided with a cooling water channel. The utility model discloses an annealing and cooling device for hot pressing molds, which can directly contact the hot pressing molds through the bottom plate and the pressure plate, and anneal and cool the hot pressing molds and products by heat conduction, thereby increasing the stability of the products during annealing and cooling, and thus increasing the quality of the products.

Description

Annealing and cooling device for hot pressing mold

Technical Field

The utility model relates to the technical field of heat treatment, in particular to an annealing and cooling device for a hot pressing die.

Background Art

Hot pressing is a simple and common processing method in the non-metal processing industry. The process mainly uses heating to process the mold and the product to soften or melt the product placed in the hot pressing mold, and the gravity of the mold itself is used as the pressure for product molding. After the hot pressing mold and the product go through the annealing and cooling process, the product in the mold cavity will gradually cool and harden, and finally the finished model can be taken out.

During the annealing and cooling process of the hot pressing mold, the temperature of the mold needs to be controlled to ensure the quality and life of the mold. In the prior art, air cooling is often used to control the temperature of the hot pressing mold, but the air cooling method has poor effects on the annealing and cooling of the hot pressing mold, and is not ideal for controlling the temperature of the hot pressing mold, thereby affecting the quality of the product.

Utility Model Content

The utility model aims to provide an annealing and cooling device for a hot pressing mold, which can directly contact the hot pressing mold through a bottom plate and a pressing plate, and anneal and cool the hot pressing mold and the product by heat conduction, thereby increasing the stability of the product during annealing and cooling, and thus increasing the quality of the product.

To achieve the above-mentioned purpose, the technical solution adopted by the utility model is: an annealing and cooling device for a hot pressing mold, comprising a furnace, and a plurality of annealing modules and cooling modules that can be embedded in the furnace cavity;

The annealing module and the cooling module both include a bottom plate and a pressing plate arranged relatively in the furnace cavity, and the pressing plate is driven by a lifting mechanism and can be close to the surface of the hot pressing mold;

The pressing plate and/or the bottom plate on the annealing module can heat the hot pressing mold;

A cooling water channel is provided in the pressure plate and/or the bottom plate on the cooling module.

In a preferred embodiment of the utility model, the lifting mechanism includes a mounting plate that is detachably connected and embedded in the furnace, and a gantry bracket arranged on the mounting plate, a first cylinder is arranged on the gantry bracket, and the piston rod on the first cylinder is connected to the pressure plate through an axis bracket movably passed through the mounting plate.

In a preferred embodiment of the utility model, a secondary pressurizing mechanism is arranged on the mounting plate, and the secondary pressurizing mechanism includes a mounting frame movably arranged on the mounting plate, and a second cylinder and a connecting rod arranged on the mounting frame; the connecting rod passes through the mounting plate, and one end of the connecting rod is provided with a top plate capable of abutting against the pressure plate, and the piston rod on the second cylinder can abut against the shaft bracket.

In a preferred embodiment of the utility model, the top plate is provided with a plurality of guide shafts which are movably arranged on the mounting plate and are coaxially arranged with the connecting rod.

In a preferred embodiment of the utility model, the shaft support and the mounting frame both include a plurality of connecting shafts that can be movably inserted into the mounting plate, and the connecting shafts on the shaft support movably penetrate the mounting frame.

In a preferred embodiment of the utility model, a plurality of the connecting shafts are coaxially arranged with the piston rods on the first cylinder and the second cylinder.

The beneficial effects of the utility model are:

The bottom plate and the pressure plate can be in direct contact with the hot pressing mold, and the hot pressing mold and the product can be annealed by heat conduction, thereby increasing the stability of the annealed product. Through the mutual cooperation of multiple cooling modules, the cooling rate of the hot pressing mold and the product can be effectively controlled to prevent the product from cooling too fast and cracking, or even directly breaking, thereby increasing the quality of the product.

BRIEF DESCRIPTION OF THE DRAWINGS

The utility model is further described below in conjunction with the accompanying drawings and embodiments.

1 is a schematic structural diagram of an annealing and cooling device for a hot pressing mold in a preferred embodiment of the utility model;

FIG2 is a schematic diagram of the structure of an annealing module in a preferred embodiment of the present utility model;

FIG3 is a schematic diagram of the structure of a cooling module in a preferred embodiment of the present utility model;

Among them, 1. furnace; 2. annealing module; 3. cooling module; 4. bottom plate; 5. pressure plate; 6. mounting plate; 7. gantry bracket; 8. first cylinder; 9. shaft bracket; 10. mounting frame; 11. second cylinder; 12. connecting rod; 13. top plate; 14. guide shaft; 15. connecting shaft.

DETAILED DESCRIPTION

The present invention will now be further described in detail in conjunction with the accompanying drawings and embodiments. These drawings are simplified schematic diagrams that only illustrate the basic structure of the present invention in a schematic manner, and therefore only show the components related to the present invention.

It should be noted that if there are directional indications (such as up, down, bottom, top, etc.) involved in this embodiment, the directional indication is only used to explain the relative position relationship, movement, etc. between the components in a certain specific posture. If the specific posture changes, the directional indication will also change accordingly. The terms "first" and "second" are only used for descriptive purposes and cannot be understood as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Therefore, the features defined as "first" and "second" may explicitly or implicitly include one or more of the features. Unless otherwise clearly specified and defined, the terms "set", "connected", and "connected" should be understood in a broad sense, for example, it can be a fixed connection, a detachable connection, or an integral connection; it can be directly connected, or indirectly connected through an intermediate medium, or it can be the internal connection of two components. For ordinary technicians in this field, the specific meanings of the above terms in this utility model can be understood according to specific circumstances.

As shown in Fig. 1 to Fig. 3, an annealing and cooling device for a hot pressing mold includes a furnace 1, and a plurality of annealing modules 2 and cooling modules 3 that can be embedded in the cavity of the furnace 1;

The annealing module 2 and the cooling module 3 both include a bottom plate 4 and a pressing plate 5 which are relatively arranged in the cavity of the furnace 1, and the pressing plate 5 is driven by a lifting mechanism and can be close to the surface of the hot pressing mold;

The pressing plate 5 and/or the bottom plate 4 on the annealing module 2 can heat the hot pressing mold. A heating device such as a heating rod can be provided inside the pressing plate 5 and/or the bottom plate 4 on the annealing module 2 to increase their temperature and heat the hot pressing mold.

A cooling water channel is provided in the pressure plate 5 and/or the bottom plate 4 on the cooling module 3 .

Specifically, the hot pressing mold and the product therein after preliminary heating will go through the two steps of annealing and cooling in sequence when passing through the furnace 1, wherein when the hot pressing mold passes through the annealing module 2, the lifting mechanism can drive the pressing plate 5 to abut against the hot pressing mold, and make the upper and lower surfaces of the hot pressing mold closely contact with the pressing plate 5 and the bottom plate 4 respectively, and the hot pressing mold can be heated for a second time by the pressing plate 5 and/or the bottom plate 4 on the annealing module 2. Preferably, taking glass products as an example, the product in the hot pressing mold can be heated by the pressing plate 5 and/or the bottom plate 4 on the annealing module 2, that is, the glass in the hot pressing mold is heated to a certain temperature lower than the glass transition temperature, so as to eliminate the stress in the glass material. At the same time, in order to facilitate continuous operation, the lifting mechanism in the technical solution will stay for a certain time after driving the pressing plate 5 to press down, and then drive the pressing plate 5 to lift up, and after the hot pressing mold is transferred to the next position, the pressing action of the pressing plate 5 is repeated again, so that the hot pressing mold and the product can be maintained in a certain temperature range. Through this structure, the annealing of the hot pressing mold and the product can be maintained during the process, which is beneficial to improving the quality of the product and the production efficiency.

After the hot pressing mold and the product undergo the annealing process, they will enter the cooling area in the furnace 1 cavity, namely the cooling module 3. Similarly, when the hot pressing mold passes through the cooling module 3, the lifting mechanism can drive the pressing plate 5 to rest against the hot pressing mold, and make the upper and lower surfaces of the hot pressing mold tightly contact the pressing plate 5 and the bottom plate 4 respectively. After the cooling water channel in the pressing plate 5 and/or the bottom plate 4 is connected to an external cold water source, the temperature of the hot pressing mold and the product can be reduced through the principle of heat conduction to achieve a cooling effect. Similarly, during the movement of the hot pressing mold, with the mutual cooperation of multiple cooling modules 3, the temperature of the hot pressing mold and the product will gradually decrease to prevent cracks from occurring in the product. Through this structure, while the hot pressing mold is moving in the furnace 1 cavity, through the mutual cooperation of multiple cooling modules 3, the cooling rate of the hot pressing mold and the product can be effectively controlled to prevent the product from cooling too fast and cracking, or even directly breaking.

In the above technical solution, the hot pressing mold moves in the furnace 1, and a transportation device commonly used in the prior art and capable of being used in a high temperature environment can be used to ensure the continuous operation of hot pressing molding.

Further, as shown in Fig. 2 and Fig. 3, the lifting mechanism includes a mounting plate 6 that is detachably connected and embedded on the furnace path 1, and a gantry bracket 7 that is arranged on the mounting plate 6, a first cylinder 8 is arranged on the gantry bracket 7, and a piston rod on the first cylinder 8 is connected to the pressing plate 5 through an axle bracket 9 that is movably penetrated on the mounting plate 6. Through the first cylinder 8 and the axle bracket 9, the pressing plate 5 can be driven to rise and fall, and then the pressing plate 5 can be pressed down on the hot pressing mold, so that the hot pressing mold and the pressing plate 5 and the bottom plate 4 are in a fitted state. At the same time, the entire lifting mechanism is arranged on the mounting plate 6, and the mounting plate 6 can be quickly installed on the furnace path 1 by bolts, and it is also convenient to quickly dismantle and replace, which is convenient for daily maintenance and maintenance of the equipment.

Furthermore, in order to make the hot pressing mold fit more closely with the pressing plate 5 and the bottom plate 4 to ensure efficient heat conduction, as shown in FIG2 , a secondary pressurizing mechanism is provided on the mounting plate 6, and the secondary pressurizing mechanism includes a mounting frame 10 movably arranged on the mounting plate 6, and a second cylinder 11 and a connecting rod 12 arranged on the mounting frame 10; the connecting rod 12 passes through the mounting plate 6, and one end of the connecting rod 12 is provided with a top plate 13 that can abut against the pressing plate 5, and the piston rod on the second cylinder 11 can abut against the shaft bracket 9.

Specifically, in the above technical scheme, after the first cylinder 8 drives the pressing plate 5 to press down on the hot pressing mold, the second cylinder 11 can be used to drive its piston rod to abut against the shaft bracket 9. Since the mounting frame 10 where the second cylinder 11 is located is movably penetrated on the mounting plate 6, under the interaction of forces, the connecting rod 12 arranged back to back with the second cylinder 11 can also extend into the furnace 1, and the top plate 13 at its end can exert pressure on the pressing plate 5, thereby making the hot pressing mold fit more closely with the pressing plate 5 and the bottom plate 4.

In this embodiment, in order to prevent the top plate 13 from rotating and deviating, a plurality of guide shafts 14 are provided on the top plate 13 movably passing through the mounting plate 6 and coaxially arranged with the connecting rod 12 .

Further, as shown in FIG. 2 , the shaft support 9 and the mounting frame 10 both include a plurality of connecting shafts 15 that can be movably mounted on the mounting plate 6. The number of connecting shafts 15 on the shaft support 9 and the mounting frame 10 is at least two, so as to enhance the stability of the shaft support 9 and the mounting frame 10 when they move up and down. At the same time, the connecting shaft 15 on the shaft support 9 movably penetrates the mounting frame 10, and the mounting frame 10 can serve as a fulcrum for the shaft support 9, further increasing the stability of the shaft support 9. At the same time, in the present technical solution, the plurality of connecting shafts 15 are coaxially arranged with the piston rods on the first cylinder 8 and the second cylinder 11.

Working principle: When the hot pressing mold passes through the annealing module 2, the lifting mechanism can drive the pressing plate 5 to abut against the hot pressing mold, and the upper and lower surfaces of the hot pressing mold are respectively in close contact with the pressing plate 5 and the bottom plate 4, and the hot pressing mold can be secondary heated and annealed by the pressing plate 5 and/or the bottom plate 4 on the annealing module 2. Through this structure, the annealing of the hot pressing mold and the product can be maintained during the process, which is conducive to improving the quality and production efficiency of the product. When the hot pressing mold passes through the cooling module 3, the lifting mechanism can drive the pressing plate 5 to abut against the hot pressing mold, and the upper and lower surfaces of the hot pressing mold are respectively in close contact with the pressing plate 5 and the bottom plate 4. After the cooling water channel in the pressing plate 5 and/or the bottom plate 4 is connected to the external cold water source, the temperature of the hot pressing mold and the product can be reduced through the principle of heat conduction to achieve the cooling effect. Through the mutual cooperation of multiple cooling modules 3, the cooling frequency of the hot pressing mold and the product can be controlled to prevent the product from cooling too fast and cracking, or even directly breaking.

The above is based on the ideal embodiment of the utility model. Through the above description, relevant personnel can make various changes and modifications without deviating from the technical concept of the utility model. The technical scope of this utility model is not limited to the content in the specification, and the technical scope must be determined according to the scope of the claims.

Claims (6)

1. An annealing and cooling device for a hot pressing mold, characterized in that it comprises a furnace (1), and a plurality of annealing modules (2) and cooling modules (3) that can be embedded in the cavity of the furnace (1); The annealing module (2) and the cooling module (3) both comprise a bottom plate (4) and a pressing plate (5) which are arranged relative to each other in the cavity of the furnace (1), and the pressing plate (5) is driven by a lifting mechanism and can be pressed against the surface of the hot pressing mold; The pressing plate (5) and/or the bottom plate (4) on the annealing module (2) are capable of heating a hot pressing mold; A cooling water channel is provided in the pressure plate (5) and/or the bottom plate (4) on the cooling module (3). 2. The annealing and cooling device for hot pressing molds according to claim 1 is characterized in that: the lifting mechanism includes a mounting plate (6) that is detachably connected and embedded in the furnace path (1), and a gantry bracket (7) arranged on the mounting plate (6), and a first cylinder (8) is arranged on the gantry bracket (7), and the piston rod on the first cylinder (8) is connected to the pressure plate (5) through an axis bracket (9) that is movably penetrated on the mounting plate (6). 3. The annealing and cooling device for hot pressing molds according to claim 2, characterized in that: a secondary pressurizing mechanism is arranged on the mounting plate (6), and the secondary pressurizing mechanism comprises a mounting frame (10) movably arranged on the mounting plate (6), and a second cylinder (11) and a connecting rod (12) arranged on the mounting frame (10); The connecting rod (12) passes through the mounting plate (6), and one end of the connecting rod is provided with a top plate (13) capable of abutting against the pressing plate (5), and the piston rod on the second cylinder (11) can abut against the shaft support (9). 4. The annealing and cooling device for hot pressing molds according to claim 3 is characterized in that: the top plate (13) is provided with a plurality of guide shafts (14) movably inserted into the mounting plate (6) and coaxially arranged with the connecting rod (12). 5. The annealing and cooling device for hot pressing molds according to claim 4 is characterized in that: the shaft bracket (9) and the mounting frame (10) both include a plurality of connecting shafts (15) that can be movably inserted into the mounting plate (6), and the connecting shafts (15) on the shaft bracket (9) movably penetrate the mounting frame (10). 6. The annealing and cooling device for hot pressing molds according to claim 5, characterized in that: the plurality of connecting shafts (15) are coaxially arranged with the piston rods on the first cylinder (8) and the second cylinder (11).