CN209974605U - Rotary integrated molding equipment - Google Patents

Abstract

The utility model provides an integrated moulding-pressing equipment of rotation type, which comprises a supporting fram, the well lower part of support frame is equipped with the mounting panel along the horizontal direction, the middle part of mounting panel is triangle-shaped and arranges and is equipped with and be columniform cooling station board, add heat station board and mould pressing station board, the cooling station board is located the front side of heating station board and mould pressing station board, it is located the right side of mould pressing station board to add the heat station board, the mould has all been placed on cooling station board, add and be equipped with the lower heating device who is used for the heated mould in heat station board and the mould pressing station board, it is equipped with the lower cooling device who is used for cooling off the mould in the cooling station board, still including reciprocating the setting and being in stamping bars on the support frame, stamping bars are equipped with three and are triangle-shaped and arrange the setting, the bottom of three stamping bars all is equipped with. The utility model has the advantages of simple structure, low cost, low error rate, low energy consumption, small occupied space and the like.

Description

Rotary integrated molding equipment

Technical Field

The utility model belongs to the technical field of the optical glass lens is made, concretely relates to integrated molding equipment of rotation type.

Background

At present, in the optical glass lens manufacturing enterprises in china, the molding equipment used is basically at the stage of being dependent on import, and the market is dominated by the equipment produced by toshiba japan and TDK in korea. The process principle of the device is that the mould pressing production of the lens is finished after the assembly line type multiple stations are relayed, for example, the manufacturing device of the glass forming body disclosed in the patent document (with the patent publication number of CN105377775A) comprises a plurality of heating stations, a pressurizing station and a cooling station, and glass material is sequentially passed through the heating stations, the pressurizing stations and the cooling station to respectively relay and finish a series of production actions of heating, stamping and cooling of the product, thereby continuously producing the glass lens.

The process has the advantages of high production efficiency, simple structure and easy maintenance. However, a plurality of molds are used in the production process, the service life of the mold can be greatly shortened by repeatedly raising and lowering the temperature of the mold in a large range (between the room temperature of 24 ℃ and the temperature of 539 ℃), and the production process by utilizing the process occupies a large amount of space, and has the disadvantages of high energy consumption, high error probability and high cost due to a plurality of stations.

SUMMERY OF THE UTILITY MODEL

The utility model discloses a solve the weak point among the prior art, provide a station that needs when reducing man-hour, simple structure, it is with low costs, the error rate is low, the energy consumption is low, the little integrated molding equipment of rotation type of occupation space.

In order to solve the technical problem, the utility model adopts the following technical scheme:

a rotary integrated die pressing device comprises a support frame, wherein a mounting plate is arranged at the middle lower part of the support frame along the horizontal direction, a cylindrical cooling station plate, a cylindrical heating station plate and a cylindrical die pressing station plate are arranged in the middle of the mounting plate in a triangular mode, the cooling station plate is positioned on the front sides of the heating station plate and the die pressing station plate, the heating station plate is positioned on the right side of the die pressing station plate, dies are respectively placed on the cooling station plate, the heating station plate and the die pressing station plate, lower heating devices for heating the dies are arranged in the heating station plate and the die pressing station plate, and lower cooling devices for cooling the dies are arranged in the cooling station plate;

the stamping device is characterized by further comprising three stamping rods which can be vertically moved and arranged on the supporting frame, the stamping rods are arranged in a triangular arrangement mode, cylindrical protective covers with sealed upper ends are arranged at the bottom ends of the three stamping rods, the inner diameter of each protective cover is matched with the outer diameters of the cooling station plate, the heating station plate and the die pressing station plate, the protective covers at the bottom ends of the three stamping rods are coaxially arranged with the cooling station plate, the heating station plate and the die pressing station plate respectively, upper heating devices for heating dies are arranged in the protective covers coaxially arranged with the heating station plate and the die pressing station plate, and upper cooling devices for cooling the dies are arranged in the protective covers coaxially arranged with the cooling station plate;

the upper and lower driving device is used for driving the stamping rod to move up and down so as to drive the protection cover to move up and down;

the rotary driving device is used for driving the die to rotate on the cooling station plate, the heating station plate and the die pressing station plate;

preferably, the rotary driving device comprises a shifting fork and a shifting fork servo motor, the shifting fork servo motor is positioned in a support frame below the mounting plate, the shifting fork comprises three shifting rods, one end of each shifting rod is fixedly connected with the other end of each shifting rod, an angle between every two shifting rods is 120 degrees, hook rods are fixed to the other ends of the three shifting rods, a through hole is formed in a connecting part of the three hook rods, an output shaft of the shifting fork servo motor is connected with a rotating rod, and the other end of the rotating rod is inserted into the through hole and is fixedly connected with;

preferably, the support frame is provided with a guide rod support, the up-down driving device further comprises three driving servo motors which are fixedly arranged on the guide rod support in a triangular arrangement, output shafts of the three driving servo motors are fixedly connected with lead screws, the upper ends of the three stamping rods are respectively in threaded connection with the lead screws on the output shafts of the three driving servo motors, and the three driving servo motors respectively drive the three lead screws to rotate so as to drive the three stamping rods to move up and down;

preferably, the three stamping rods are all of a hollow structure, the upper ends of the three stamping rods are respectively sleeved on the three lead screws through lead screw nuts, and the lower ends of the three lead screws respectively extend into hollow cavities of the three stamping rods;

preferably, the upper part of the guide rod bracket is provided with an upper support plate, a lower support plate is arranged between the guide rod bracket and the support frame, a guide rod is arranged in the guide rod bracket, one end of the guide rod is fixedly connected with the upper support plate, the other end of the guide rod is fixedly connected with the lower support plate, the guide rod is sleeved with a guide sleeve fixedly connected with the stamping rod, and the guide sleeve slides up and down along the guide rod;

preferably, six guide rods are arranged in the guide rod bracket;

preferably, the device also comprises a first temperature monitoring device for monitoring heating temperatures in the heating station plate and the die pressing station plate and heating temperatures in the protective covers coaxially arranged with the heating station plate and the die pressing station plate, and a second temperature monitoring device for monitoring cooling temperatures in the cooling station plate and cooling temperatures in the protective covers coaxially arranged with the cooling station plate;

preferably, the upper heating device and the lower heating device are both heating plates, the upper cooling device and the lower cooling device are both cooling plates, and the first temperature monitoring device and the second temperature monitoring device are both temperature sensors;

preferably, the cooling station plate, the heating station plate and the die pressing station plate are all provided with a vacuum pumping hole and a nitrogen gas supply hole, and the cooling station plate is provided with a water inlet hole and a water outlet hole;

preferably, the peripheral wall of the protective cover is a double-layer hollow structure, and the hollow structure of the protective cover is filled with a heat insulating material.

Adopt above-mentioned technical scheme, the utility model discloses following beneficial effect has:

(1) the utility model discloses collect heating, mould pressing and cooling of optical glass lens in process of production as an organic whole, put into the optical glass lens the utility model discloses a mould on the cooling station board, the utility model discloses heat earlier according to optical glass lens, then the mould pressing, the cooling is taken out at last, only need one person to operate at this in-process and can accomplish, compare with prior art, the manufacturing installation of the glass shaping body among the prior art, including a plurality of heating stations, pressurization station, cooling station, glass nitre material loops through each heating station, pressurization station, cooling station, accomplishes the heating of product, punching press, cooling a series of production actions respectively in the relay, thereby produce the glass lens continuously, the utility model discloses not only reduced the mould of station with using, still saved a large amount of spaces, saved the cost, the error rate is low;

(2) the utility model discloses be equipped with rotary driving device, rotary driving device is used for the drive the mould rotates on cooling station board, heating station board and mould pressing station board, in this use neotype use, at first put into first piece optical glass lens in the mould on the cooling station board, then start the utility model discloses, shift fork servo motor drives shift fork drive mould rotation 120, and mould on the cooling station board rotates and heats on heating station board, and mould rotation 120 on the heating station board is to the mould pressing station board, and mould rotation 120 on the mould pressing station board is to the cooling station board, then puts into second piece optical glass lens in the mould on the mould pressing station board again, and after first piece optical glass lens heating finishes, shift fork servo motor drives shift fork drive cooling station board, heats mould rotation 120 on station board and the mould pressing station board once more, the first optical glass lens reaches the mould pressing station plate to be mould pressed, the second optical glass lens reaches the heating station plate to be heated, a third optical glass lens is placed in the mould on the cooling station plate, after the mould pressing of the first optical glass lens is finished and the heating of the second optical glass lens is finished, the shifting fork servo motor drives the shifting fork again to drive the mould on the cooling station plate, the heating station plate and the mould on the mould pressing station plate to rotate clockwise by 120 degrees, the first optical glass lens reaches the cooling station plate to be cooled and taken out, the second optical glass lens reaches the mould pressing station plate to be mould pressed, the third optical glass lens reaches the heating station plate to be heated, and the analogy is repeated, the optical glass lenses complete the heating, mould pressing and cooling once in the utility model, and only three moulds are needed in the heating, mould pressing and cooling processes, the occupied space is small, the number of stations during production is small, the cost is low, and in the production process, the used human resources are few.

(3) The protective cover of the utility model adopts a double-layer hollow structure, and the heat insulating material is filled in the hollow structure of the protective cover, thereby ensuring that each protective cover is not interfered by other adjacent protective covers in the production process and the quality of the produced product is stable;

(4) the utility model discloses a cooling station board, heating station board and mould pressing station board are all equipped with evacuation hole and nitrogen gas supply hole, are equipped with inlet opening and apopore on the cooling station board, compare with prior art, when cooling the product among the prior art, need supporting cooling system to ensure the constant temperature of coolant liquid, and the energy consumption is high, the utility model discloses when cooling, directly insert coolant liquid (running water) on the cooling station board and can satisfy the needs of production and the utility model discloses the coolant liquid (running water) volume of consumption is few, and the energy consumption is low, has saved the cost of production;

to sum up, the utility model has the advantages of simple structure, with low costs, the error rate is low, and the energy consumption is low, and occupation space is little.

Drawings

Fig. 1 is a schematic structural diagram of the present invention;

FIG. 2 is a schematic view of the cooling station of FIG. 1 with the cooling station removed;

FIG. 3 is a schematic view of the heating station and the molding station of FIG. 1 with the heating station and the molding station removed;

FIG. 4 is a top view of the fork of FIG. 1 in use with a cooling station plate, a heating station plate, and a molding station plate.

Detailed Description

As shown in fig. 1-4, the utility model discloses a rotary integrated molding press, including support frame 1, the middle and lower part of support frame 1 is equipped with mounting panel 2 along the horizontal direction, the middle part of mounting panel 2 is triangle-shaped and arranges and is equipped with and is columniform cooling station board 3, heat station board 4 and mould pressing station board 5, cooling station board 3 is located the front side of heating station board 4 and mould pressing station board 5, heat station board 4 is located the right side of mould pressing station board 5, the mould has all been placed on cooling station board 3, heat station board 4 and the mould pressing station board 5, be equipped with the lower heating device who is used for heating the mould in heating station board 4 and the mould pressing station board 5, be equipped with the lower cooling device who is used for cooling the mould in the cooling station board 3;

the stamping device is characterized by further comprising three stamping rods 6 which can be vertically moved and arranged on the support frame 1, the stamping rods 6 are arranged in a triangular arrangement mode, cylindrical protective covers 7 with sealed upper ends are arranged at the bottom ends of the three stamping rods 6, the inner diameters of the protective covers 7 are matched with the outer diameters of the cooling station plate 3, the heating station plate 4 and the die pressing station plate 5, the protective covers 7 at the bottom ends of the three stamping rods 6 are coaxially arranged with the cooling station plate 3, the heating station plate 4 and the die pressing station plate 5 respectively, upper heating devices for heating dies are arranged in the protective covers 7 which are coaxially arranged with the heating station plate 4 and the die pressing station plate 5, and upper cooling devices for cooling the dies are arranged in the protective covers 7 which are coaxially arranged with the cooling station plate 3;

the device also comprises an up-down driving device, wherein the up-down driving device is used for driving the stamping rod 6 to move up and down so as to drive the protective cover 7 to move up and down;

the device also comprises a rotary driving device, wherein the rotary driving device is used for driving the mould to rotate on the cooling station plate 3, the heating station plate 4 and the mould pressing station plate 5;

the rotary driving device comprises a shifting fork and a shifting fork servo motor 20, the shifting fork servo motor 20 is positioned in the support frame 1 below the mounting plate 2, the shifting fork comprises three shifting rods 8, one ends of the shifting rods are fixedly connected together, the angle between every two shifting rods 8 is 120 degrees, the other ends of the three shifting rods 8 are respectively fixed with a hook rod 9, a through hole 10 is formed in the connecting part of the three hook rods 9, an output shaft of the shifting fork servo motor 20 is connected with a rotating rod, and the other end of the rotating rod is inserted into the through hole 10 and is fixedly connected with the connecting part of the;

the support frame 1 is provided with a guide rod bracket 11, the up-down driving device further comprises three driving servo motors 12 which are fixedly arranged on the guide rod bracket 11 and arranged in a triangular shape, output shafts of the three driving servo motors 12 are fixedly connected with screw rods 13, the upper ends of the three stamping rods 6 are respectively in threaded connection with the screw rods 13 on the output shafts of the three driving servo motors 12, and the three driving servo motors 12 respectively drive the three screw rods 13 to rotate so as to drive the three stamping rods 6 to move up and down;

the three stamping rods 6 are all of a hollow structure, the upper ends of the three stamping rods 6 are respectively sleeved on the three lead screws 13 through lead screw nuts, and the lower ends of the three lead screws 13 respectively extend into hollow cavities of the three stamping rods 6;

an upper supporting plate 14 is arranged at the upper part of the guide rod support 11, a lower supporting plate 15 is arranged between the guide rod support 11 and the support frame 1, a guide rod 16 is arranged in the guide rod support 11, one end of the guide rod 16 is fixedly connected with the upper supporting plate 14, the other end of the guide rod 16 is fixedly connected with the lower supporting plate 15, a guide sleeve 17 fixedly connected with the stamping rod 6 is sleeved on the guide rod 16, and the guide sleeve 17 slides up and down along the guide rod 16;

six guide rods 16 are arranged in the guide rod 16 bracket 11;

the device also comprises a first temperature monitoring device for monitoring heating temperatures in the heating station plate 4 and the die pressing station plate 5 and heating temperatures in the protective cover 7 coaxially arranged with the heating station plate 4 and the die pressing station plate 5, and a second temperature monitoring device for monitoring cooling temperatures in the cooling station plate 3 and cooling temperatures in the protective cover 7 coaxially arranged with the cooling station plate 3;

the upper heating device and the lower heating device are both heating plates 18, the upper cooling device and the lower cooling device are both cooling plates 19, and the first temperature monitoring device and the second temperature monitoring device are both temperature sensors;

the cooling station plate 3, the heating station plate 4 and the die pressing station plate 5 are all provided with a vacuum pumping hole and a nitrogen gas supply hole, and the cooling station plate 3 is provided with a water inlet hole and a water outlet hole;

the peripheral wall of the protective cover 7 is a double-layer hollow structure, and heat insulation materials are filled in the hollow structure of the protective cover 7.

The utility model discloses a concrete use as follows:

the utility model has three stations, namely a cooling station, a heating station and a mould pressing station, which correspond to a cooling station plate 3, a heating station plate 4 and a mould pressing station plate 5 respectively, the cooling station plate 3 of the utility model undertakes cooling the mould and replacing the new production product (optical glass lens) to be put into the function of the utility model, the heating station plate 4 and the mould pressing station plate 5 are responsible for heating and mould pressing the production product (optical glass lens); the cooling station plate 3, the heating station plate 4 and the mould pressing station plate 5 are all provided with moulds which are respectively used for the same time, after the operation of the current station is finished, the shifting forks arranged in the gaps among the cooling station plate 3, the heating station plate 4 and the die pressing station plate 5 rotate to simultaneously rotate the dies on the three stations to the next station, namely, the mold finishes one production process after sequentially finishing the three stations of heating, molding and cooling, and the internal diameters of the three protective covers 7 are matched with the external diameters of the cooling station plate 3, the heating station plate 4 and the die pressing station plate 5 which are coaxially arranged with the three protective covers 7 respectively, so that the three protective covers 7 are rapidly attached to the cooling station plate 3, the heating station plate 4 and the die pressing station plate 5 which are coaxially arranged with the three protective covers 7, and the heating or cooling of dies on the cooling station plate 3, the heating station plate 4 and the die pressing station plate 5 is completed.

The utility model integrates the heating station, the mould pressing station and the cooling station in the production process of the optical glass lens, when the utility model is used, firstly, a first optical glass lens is put into the mould on the cooling station plate 3, then the utility model is started, the shifting fork servo motor 20 drives the shifting fork to drive the moulds on the cooling station plate 3, the heating station plate 4 and the mould pressing station plate 5 to rotate clockwise 120 degrees, then the shifting fork servo motor 20 drives the shifting fork to rotate anticlockwise to enable the shifting fork to be positioned in the gap between the cooling station plate 3, the heating station plate 4 and the mould pressing station plate 5, the mould provided with the first optical glass lens reaches the heating station plate 4, then the three driving servo motors 12 are started, the three driving servo motors respectively drive the three lead screws 13 to rotate clockwise, the three lead screws 13 rotate clockwise to drive the three punching rods 6 to move downwards, three stamping rods 6 drive three protective covers 7 to be respectively buckled with a cooling station plate 3, a heating station plate 4 and a die pressing station plate 5, at the moment, three driving servo motors 12 stop working, the heating station plate 4 and a heating plate 18 in the protective cover 7 coaxially arranged with the heating station plate 4 heat a die on the heating station plate 4 and a first optical glass lens in the die, the heating station plate 4 is vacuumized through a vacuumizing hole on the heating station plate 4 and is filled with nitrogen through a nitrogen supply hole, after the first optical glass lens is heated, the three driving servo motors 12 are started, the three driving servo motors respectively drive three lead screws 13 to rotate anticlockwise, the three lead screws 13 rotate anticlockwise to drive the three stamping rods 6 to move upwards, the three stamping rods 6 drive the three protective covers 7 to be respectively separated from the cooling station plate 3, the heating station plate 4 and the die pressing station plate 5, at this time, the three driving servo motors 12 stop working;

at the moment, a second piece of optical glass is placed in a mold on a cooling station plate 3, then a shifting fork servo motor 20 drives the shifting fork to drive the cooling station plate 3, the heating station plate 4 and molds on a pressing station plate 5 to rotate 120 degrees clockwise again, the molds on the cooling station plate 3 rotate 120 degrees to the heating station plate 4 to be heated, the molds on the heating station plate 4 rotate 120 degrees to the pressing station plate 5, the molds on the pressing station plate 5 rotate 120 degrees to the cooling station plate 3, the first piece of optical glass reaches the pressing station plate 5, the second piece of optical glass reaches the heating station plate 4, the shifting fork servo motor 20 drives the shifting fork to rotate anticlockwise to enable the shifting fork to be positioned in a gap between the cooling station plate 3, the heating station plate 4 and the pressing station plate 5, then three driving servo motors 12 are started, and three driving servo motors respectively drive three lead screws 13 to rotate clockwise, the three lead screws 13 rotate clockwise to drive the three stamping rods 6 to move downwards, the three stamping rods 6 drive the three protective covers 7 to be respectively buckled with the cooling station plate 3, the heating station plate 4 and the mould pressing station plate 5, at the moment, the three driving servo motors 12 stop working, the heating station plate 4 and the heating plate 18 in the protective cover 7 coaxially arranged with the heating station plate 4 heat a mould on the heating station plate 4 and a second optical glass lens in the mould, the mould pressing station plate 5 and the heating plate 18 in the protective cover 7 coaxially arranged with the mould pressing station plate 5 continuously heat and mould press a first optical glass lens in the mould on the mould pressing station plate 5, the heating station plate 4 is vacuumized through a vacuumizing hole on the heating station plate 4 and is filled with nitrogen through a nitrogen gas supply hole, the heating station plate 4 is vacuumized through a vacuumizing hole on the mould pressing station plate 5 and is filled with nitrogen gas through the nitrogen gas supply hole, when the second optical glass lens is heated and the first optical glass lens is molded, the three driving servo motors 12 are started, the three driving servo motors respectively drive the three lead screws 13 to rotate anticlockwise, the three lead screws 13 rotate anticlockwise to drive the three stamping rods 6 to move upwards, the three stamping rods 6 drive the three protective covers 7 to be separated from the cooling station plate 3, the heating station plate 4 and the molding station plate 5, and at the moment, the three driving servo motors 12 stop working;

at the moment, a third piece of optical glass is placed in a mold on a cooling station plate 3, then a shifting fork servo motor 20 drives the shifting fork to drive the cooling station plate 3, the heating station plate 4 and molds on a mold pressing station plate 5 to rotate 120 degrees clockwise again, the molds on the cooling station plate 3 rotate 120 degrees to the heating station plate 4 to be heated, the molds on the heating station plate 4 rotate 120 degrees to the mold pressing station plate 5, the molds on the mold pressing station plate 5 rotate 120 degrees to the cooling station plate 3, the first piece of optical glass reaches the cooling station plate 3, the second piece of optical glass reaches the mold pressing station plate 5, the third piece of optical glass reaches the heating station plate 4, the shifting fork servo motor 20 drives the shifting fork to rotate anticlockwise to enable the shifting fork to be positioned in a gap between the cooling station plate 3, the heating station plate 4 and the mold pressing station plate 5, and then three driving servo motors 12 are started, three driving servo motors respectively drive three lead screws 13 to rotate clockwise, the three lead screws 13 rotate clockwise to drive three stamping rods 6 to move downwards, the three stamping rods 6 drive three protective covers 7 to be respectively buckled with a cooling station plate 3, a heating station plate 4 and a mould pressing station plate 5, at the moment, three driving servo motors 12 stop working, the heating station plate 4 and a heating plate 18 in the protective cover 7 which is coaxially arranged with the heating station plate 4 heat a mould on the heating station plate 4 and a third optical glass lens in the mould, the mould pressing station plate 5 and the heating plate 18 in the protective cover 7 which is coaxially arranged with the mould pressing station plate 5 continuously heat and mould press a second optical glass lens in the mould on the mould pressing station plate 5, the cooling station plate 3 and a cooling plate 19 in the protective cover 7 which is coaxially arranged with the cooling station plate 3 cool the mould on the cooling station plate 3 and a first optical glass lens in the mould, vacuumizing the interior of the heating station plate 4 through a vacuumizing hole on the heating station plate 4, filling nitrogen through a nitrogen gas supply hole, vacuumizing the interior of the heating station plate 4 through a vacuumizing hole on the mould pressing station plate 5, filling nitrogen through a nitrogen gas supply hole, vacuumizing the interior of the heating station plate 4 through a vacuumizing hole on the cooling station plate 3, filling nitrogen through a nitrogen gas supply hole, filling cooling liquid into the cooling station plate 3 through a water inlet hole on the cooling station plate 3, discharging the cooling liquid through a water outlet hole on the cooling station plate 3, finishing mould pressing of a second optical glass lens when a third optical glass lens is heated, starting three driving servo motors 12 after a first optical glass lens is cooled, respectively driving three lead screws 13 to rotate, and driving three stamping rods 6 to move upwards by the three lead screws 13 in a counterclockwise rotation mode, the three stamping rods 6 drive the three protective covers 7 to be separated from the cooling station plate 3, the heating station plate 4 and the die pressing station plate 5 respectively, at the moment, the three driving servo motors 12 stop working, the first optical glass lens which is cooled is taken down, the fourth optical glass lens is put in, the above operation steps are repeated, and the like, the above operation is completed in the using process of the utility model;

the utility model discloses at the in-process that uses, first temperature monitoring device and second temperature monitoring device real-time supervision cooling station board 3, heat station board 4 and mould pressing station board 5 and with the temperature in the safety cover 7 that cooling station board 3, heating station board 4 and 5 coaxial lines of mould pressing station board set up.

The present embodiment is not intended to limit the shape, material, structure, etc. of the present invention in any form, and all of the technical matters of the present invention belong to the protection scope of the present invention to any simple modification, equivalent change and modification made by the above embodiments.

Claims (10)

1. The utility model provides an integrated moulding-pressing equipment of rotation type which characterized in that: the cooling station plate, the heating station plate and the die pressing station plate are all provided with dies, lower heating devices for heating the dies are arranged in the heating station plate and the die pressing station plate, and lower cooling devices for cooling the dies are arranged in the cooling station plate;

the stamping device is characterized by further comprising three stamping rods which can be vertically moved and arranged on the supporting frame, the stamping rods are arranged in a triangular arrangement mode, cylindrical protective covers with sealed upper ends are arranged at the bottom ends of the three stamping rods, the inner diameter of each protective cover is matched with the outer diameters of the cooling station plate, the heating station plate and the die pressing station plate, the protective covers at the bottom ends of the three stamping rods are coaxially arranged with the cooling station plate, the heating station plate and the die pressing station plate respectively, upper heating devices for heating dies are arranged in the protective covers coaxially arranged with the heating station plate and the die pressing station plate, and upper cooling devices for cooling the dies are arranged in the protective covers coaxially arranged with the cooling station plate;

the upper and lower driving device is used for driving the stamping rod to move up and down so as to drive the protection cover to move up and down;

the die is characterized by further comprising a rotary driving device, wherein the rotary driving device is used for driving the die to rotate on the cooling station plate, the heating station plate and the die pressing station plate.

2. A rotary integrated die press apparatus according to claim 1, wherein: the rotary driving device comprises a shifting fork and a shifting fork servo motor, the shifting fork servo motor is located in a support frame below the mounting plate, the shifting fork comprises three shifting rods with one ends fixedly connected together, and an angle between every two shifting rods is 120 degrees, the other ends of the three shifting rods are all fixed with hook rods, connecting portions of the three hook rods are provided with through holes, an output shaft of the shifting fork servo motor is connected with a rotating rod, and the other ends of the rotating rod are inserted into the through holes and are fixedly connected with the connecting portions of the three shifting rods.

3. A rotary integrated die press apparatus according to claim 1, wherein: the upper end of each punching rod is in threaded connection with the corresponding screw rod on the output shaft of the corresponding driving servo motor, and the three driving servo motors respectively drive the three screw rods to rotate so as to drive the three punching rods to move up and down.

4. A rotary integrated die press apparatus according to claim 3, wherein: the three stamping rods are all of a hollow structure, the upper ends of the three stamping rods are respectively sleeved on the three lead screws through lead screw nuts, and the lower ends of the three lead screws respectively extend into hollow cavities of the three stamping rods.

5. A rotary integrated die press apparatus according to claim 3, wherein: the upper portion of the guide rod support is provided with an upper supporting plate, a lower supporting plate is arranged between the guide rod support and the supporting frame, a guide rod is arranged in the guide rod support, one end of the guide rod is fixedly connected with the upper supporting plate, the other end of the guide rod is fixedly connected with the lower supporting plate, a guide sleeve fixedly connected with the stamping rod is sleeved on the guide rod, and the guide sleeve slides up and down along the guide rod.

6. A rotary integrated die press apparatus according to claim 5, wherein: six guide rods are arranged in the guide rod bracket.

7. A rotary integrated die press apparatus according to claim 1, wherein: the device comprises a heating station plate, a mould pressing station plate, a first temperature monitoring device and a second temperature monitoring device, wherein the first temperature monitoring device is used for monitoring heating temperature in the heating station plate and the mould pressing station plate and heating temperature in a protective cover coaxially arranged with the heating station plate and the mould pressing station plate, and the second temperature monitoring device is used for monitoring cooling temperature in the cooling station plate and cooling temperature in the protective cover coaxially arranged with the cooling station plate.

8. A rotary integrated die press apparatus according to claim 7, wherein: go up heating device and heating device down and be the hot plate, go up cooling device and cooling device down and be the cooling plate, first temperature monitoring device and second temperature monitoring device are temperature sensor.

9. A rotary integrated die press apparatus according to claim 1, wherein: all be equipped with evacuation hole and nitrogen gas air feed hole on cooling station board, heating station board and the mould pressing station board, be equipped with inlet opening and apopore on the cooling station board.

10. A rotary integrated die press apparatus according to claim 1, wherein: the peripheral wall of the protective cover is of a double-layer hollow structure, and heat insulation materials are filled in the hollow structure of the protective cover.

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