CN115257134A - Laminating machine for manufacturing 5G communication module and laminating method thereof - Google Patents

Abstract

The invention relates to the technical field of 5G communication module manufacturing, in particular to a laminating machine for 5G communication module manufacturing, which comprises a bottom plate, wherein a first baffle plate and a second baffle plate are respectively arranged on two sides of the upper end surface of the bottom plate; a plurality of first die frames are arranged on the inner side surface of the first baffle plate and one side surface of the partition plate in a vertically sliding manner, an extrusion die is arranged on each first die frame in a sliding manner, and a plurality of second die frames are arranged on the inner side surface of the second baffle plate and the other side surface of the partition plate in a vertically sliding manner; the bottom plate front side slides and sets up the backup pad, and the backup pad up end is kept away from the vertical second backup pad that sets up in bottom plate one side, and the vertical slip of second backup pad medial surface sets up electric telescopic handle, and electric telescopic handle front end face sets up the picture peg, and the bottom plate back sets up steam pressure equipment and cooling cycle structure respectively. The invention adopts a mechanical structure to replace hands to take out the extrusion die, and can effectively prevent scalding due to high temperature.

Description

Laminating machine for manufacturing 5G communication module and laminating method thereof

Technical Field

The invention relates to a laminating machine for manufacturing a 5G communication module, in particular to a laminating machine for manufacturing a 5G communication module and a laminating method thereof, belonging to the technical field of manufacturing of 5G communication modules.

Background

The 5G communication module is a module component which depends on a 5G network for communication, and because the 5G network is used for communication, the communication effect is better, the response is quicker, the 5G communication module is an indispensable technology in the current communication era, the specific expression forms of the 5G communication module are various, and the audio communication is performed by depending on the network more commonly;

in the manufacturing process of the 5G module, the 5G module can be molded finally only by carrying out pressing treatment on the multilayer substances, and a laminating machine is required to be used for processing in the pressing step, and the laminating machine is used for pressurizing and heating the multilayer substances so as to press the multilayer substances together;

however, when the existing laminating machine is used for laminating, the multi-layer material after being pressurized and heated and the laminating mold body need to be taken out by a worker with hands for carrying out the cooling and laminating of the next step, in the process of taking out the piece, due to the fact that the temperature of the mold body is high, if the protection is not proper, scalding may occur, and meanwhile, the laminating efficiency is reduced by manual switching.

Therefore, there is a need for an improved 5G communication module manufacturing to solve the above existing problems.

Disclosure of Invention

The invention aims to provide a laminating machine for manufacturing a 5G communication module and a laminating method thereof, wherein a mechanical structure is adopted to replace hands to take out an extrusion die, so that the condition of scalding due to high temperature can be effectively prevented, and meanwhile, the laminating machine has good and uniform heating and quick heat dissipation effects.

In order to achieve the purpose, the invention adopts the main technical scheme that:

a laminating machine for manufacturing a 5G communication module comprises a bottom plate, wherein a first baffle and a second baffle are respectively arranged on two sides of the upper end surface of the bottom plate, a top plate is arranged above the space between the first baffle and the second baffle, and a partition plate is vertically arranged in the middle of the upper end surface of the bottom plate;

a plurality of first die frames are arranged on the inner side surface of the first baffle plate and one side surface of the partition plate in a vertically sliding manner, an extrusion die is arranged on each first die frame in a sliding manner, and a plurality of second die frames are arranged on the inner side surface of the second baffle plate and the other side surface of the partition plate in a vertically sliding manner;

a supporting plate is arranged on the front side face of the bottom plate in a sliding mode, a second supporting plate is vertically arranged on one side, away from the bottom plate, of the upper end face of the supporting plate, an electric telescopic rod is vertically arranged on the inner side face of the second supporting plate in a sliding mode, an inserting plate is arranged on the front end face of the electric telescopic rod, and the inserting plate is used for inserting the extrusion die;

the back of the bottom plate is provided with a steam pressurizing device and a cooling circulation structure respectively, the steam pressurizing device is communicated with the inside of the first mold frame, and the cooling circulation structure is communicated with the inside of the second mold frame.

Preferably, the first baffle medial surface with the equal vertical first electronic slide rail of a plurality of that is provided with of a side of baffle, first mould frame with first electronic slide rail sliding connection, the second baffle medial surface with the equal vertical electronic slide rail of second that is provided with of another side of baffle, second mould frame with second electronic slide rail sliding connection.

Preferably, sliding grooves are formed in the upper end faces of the first die frame and the second die frame, sliding blocks are arranged on two sides of each sliding groove, sliding grooves in sliding connection with the sliding blocks are arranged on two sides of the extrusion die, copper pipes spirally arranged inside the first die frame and the second extrusion die are arranged inside the first die frame and the second extrusion die, inlet ends and outlet ends of the copper pipes protrude out of the side faces of the first die frame and the second die frame, and inserting grooves are formed in the front end face of the extrusion die.

Preferably, the vertical third electric slide rail that is provided with of medial surface of second backup pad, electric telescopic handle pass through the sliding block with third electric slide rail sliding connection, electric telescopic handle adopts multistage formula telescopic link structure, the inside first infrared inductive probe that is provided with of slot, the picture peg is kept away from electric telescopic handle's one end is provided with the infrared inductive probe of second.

Preferably, first fans are arranged on two sides of the lower end face of the bottom plate, second fans are arranged on two sides of the lower end face of the top plate, the first fans are located under the first die frame and the second die frame respectively, and the second fans are located over the first die frame and the second die frame respectively.

Preferably, the inner side of the steam pressurizing device is provided with a heat transfer pipe, the heat transfer pipe is connected with a plurality of heat transfer hoses, and the plurality of heat transfer hoses are respectively communicated with the inlet ends of the copper pipes in the first mold frames.

Preferably, the cooling circulation structure comprises a first water tank, a second water tank and a refrigeration compressor assembly, the compressor assembly is communicated with the upper portion of the second water tank through a refrigeration pipeline, the first water tank is communicated with the second water tank through a first water pump, and a second water pump is arranged in the first water tank.

Preferably, a water conveying pipe is arranged on the inner side of the first water tank, the water conveying pipe is connected with a plurality of water conveying hoses, the plurality of water conveying hoses are communicated with the open ends of the copper pipes in the second die frame, a drain pipe is arranged above the second water tank, the drain pipe is connected with a plurality of drain hoses, and the plurality of drain hoses are communicated with the outlet ends of the copper pipes in the second die frame.

Preferably, a water injection pipe is arranged on the upper end face of the first water tank, the second water pump is communicated with the water delivery pipe, and the water injection pipe is sealed through a sealing plug.

A laminating method of a laminating machine for manufacturing a 5G communication module comprises the following steps:

s1: when the module is laminated, placing a plurality of groups of multilayer substances on a plurality of extrusion dies, then sliding the extrusion dies into a plurality of first die frames, starting a steam pressurizing device, inputting heat into copper pipes in the plurality of first die frames through a heat transmission pipe and a plurality of heat transmission hoses, and heating the plurality of first die frames so as to heat the extrusion dies in a sliding groove;

s2: then, opening a first electric slide rail, laminating a plurality of first die frames in a stacking manner, and heating and extruding the multilayer substance placed on the extrusion die, wherein the heat inside the copper pipe can be discharged from an outlet end;

s3: after equipment is heated and extruded for a period of time, a plurality of first die frames are separated by using the first electric slide rail, a third electric slide rail and an electric telescopic link are driven to carry out corresponding position adjustment by using the alignment arrangement of a first infrared induction probe and a second infrared induction probe, an inserting plate is inserted into a slot, and then the extrusion dies in the first die frames are taken out by using the adjustment of the electric telescopic link and the third electric slide rail and are placed into a second die frame;

s4: work as the extrusion die slip card is gone into inside the second mould frame, open the second water pump, utilize the second water pump passes through raceway and water delivery hose with the inside water source of first water tank and carries extremely inside the second mould frame in the copper pipe, open the electronic slide rail of second simultaneously, drive a plurality of the extrusion of laminating is carried out to the second mould frame, utilizes the process the inside cooling water source of copper pipe will extrusion die carries out cooling and handles, and the cooling water through a circulation can discharge to inside the second water tank through drainage hose and drain pipe, then utilizes the compressor assembly, carries air conditioning extremely through the refrigeration pipeline inside the second water tank carries out the cooling to the water source and handles, and the water source through the cooling is in taking out extremely carry out reuse in the first water tank.

The invention has at least the following beneficial effects:

1. through the setting that utilizes third electric slide rail, first infrared inductive probe, second infrared inductive probe, picture peg, slot and electric telescopic handle can realize extrusion module's automatic switch-over, adopt mechanical structure to replace the staff with extrusion die from the regional switch-over to the regional of cooling lamination of zone pressing to can effectively prevent because the condition of scald appears in the high temperature.

2. Carry the inside water source of first water tank to the inside copper pipe of second mould frame through raceway and water delivery hose through utilizing the second water pump, utilize the cooling water source through copper intraduct to carry out cooling treatment with extrusion die, through inside a circulating cooling water can discharge to the second water tank through drainage hose and drain pipe, then utilize the compressor assembly, carry air conditioning to the second water tank through refrigeration pipeline inside, carry out the cooling treatment to the water source, the water source through the cooling is through first water pump taking out to first water tank in reuse, reach the effect of circulation cooling.

Drawings

The accompanying drawings, which are included to provide a further understanding of the application and are incorporated in and constitute a part of this application, illustrate embodiment(s) of the application and together with the description serve to explain the application and not to limit the application. In the drawings:

FIG. 1 is a schematic perspective view of the present invention;

FIG. 2 is a partial cross-sectional view of the present invention;

FIG. 3 is a side view of the steam pressurizing apparatus of the present invention;

FIG. 4 is a cross-sectional view of the interior of a first mold frame of the present invention;

FIG. 5 is a perspective view of the cooling cycle of the present invention;

FIG. 6 is a sectional view of the inside of the first water tank of the present invention;

FIG. 7 is a schematic view of the connection of the extrusion die of the present invention;

fig. 8 is a partial side view of the present invention.

In the figure, 1-a bottom plate, 2-a first baffle, 3-a second baffle, 4-a partition plate, 5-a top plate, 6-a first mold frame, 7-an extrusion mold, 8-a second mold frame, 9-a support plate, 10-a second support plate, 11-an electric telescopic rod, 12-an insert plate, 13-a steam pressurizing device, 14-a cooling circulation structure, 15-a first electric slide rail, 16-a second electric slide rail, 17-a slide groove, 18-a slide block, 19-a slide groove, 20-a copper pipe, 21-an insert groove, 22-a third electric slide rail, 23-a slide block, 24-a first infrared induction probe, 25-a second infrared induction probe, 26-a first fan, 27-a second fan, 28-a heat transfer pipe, 29-a heat transfer hose, 30-a first water tank, 31-a second water tank, 32-a compressor assembly, 33-a refrigeration pipeline, 34-a water transfer hose, 35-a water transfer pipe, 36-a first water pump, 37-a second water pump, 38-a hose, 39-a water discharge pipe, 40-a water injection pipe and 41-a water injection sealing plug.

Detailed Description

Embodiments of the present application will be described in detail with reference to the drawings and examples, so that how to implement technical means to solve technical problems and achieve technical effects of the present application can be fully understood and implemented.

As shown in fig. 1 to 8, the laminator for manufacturing a 5G communication module provided in this embodiment includes a bottom plate 1, a first baffle 2 and a second baffle 3 are respectively disposed on two sides of an upper end surface of the bottom plate 1, a top plate 5 is disposed above the first baffle 2 and the second baffle 3, and a partition plate 4 is vertically disposed in a middle portion of the upper end surface of the bottom plate 1;

a plurality of first die frames 6 are arranged on the inner side surface of the first baffle plate 2 and one side surface of the partition plate 4 in a vertically sliding manner, an extrusion die 7 is arranged on each first die frame 6 in a sliding manner, and a plurality of second die frames 8 are arranged on the inner side surface of the second baffle plate 3 and the other side surface of the partition plate 4 in a vertically sliding manner;

a supporting plate 9 is arranged on the front side face of the bottom plate 1 in a sliding mode, a second supporting plate 10 is vertically arranged on one side, far away from the bottom plate 1, of the upper end face of the supporting plate 9, an electric telescopic rod 11 is vertically arranged on the inner side face of the second supporting plate 10 in a sliding mode, an inserting plate 12 is arranged on the front end face of the electric telescopic rod 11, and the inserting plate 12 is used for inserting the extrusion die 7;

the back of the bottom plate 1 is provided with a steam pressurizing device 13 and a cooling circulation structure 14 respectively, the steam pressurizing device 13 is communicated with the inside of the plurality of first mold frames 6, and the cooling circulation structure 14 is communicated with the inside of the plurality of second mold frames 8.

Further, as shown in fig. 1, a plurality of first electric slide rails 15 are vertically arranged on the inner side surface of the first baffle 2 and the side surface of the partition plate 4, the first mold frame 6 is slidably connected with the first electric slide rails 15, a second electric slide rail 16 is vertically arranged on the inner side surface of the second baffle 3 and the other side surface of the partition plate 4, the second mold frame 8 is slidably connected with the second electric slide rails 16, the first electric slide rails 15 drive the plurality of first mold frames 6 to slide up and down, and the second electric slide rails 16 drive the second mold frame 8 to slide up and down.

Further, as shown in fig. 4 and 7, a sliding groove 17 has been all seted up to the up end of first mould frame 6 and second mould frame 8, sliding block 18 has all been provided with to the both sides of sliding groove 17, extrusion die 7's both sides all are provided with sliding block 18 sliding connection's spout 19, first mould frame 6 all is provided with the copper pipe 20 that spirals the setting with second extrusion die 8 is inside, the side of first mould frame 6 and second mould frame 8 is all outstanding to the entrance point and the exit end of copper pipe 20, slot 21 has been seted up to the preceding terminal surface of extrusion die 7.

Furthermore, as shown in fig. 1 and 8, a third electric slide rail 22 is vertically arranged on the inner side surface of the second support plate 10, the electric telescopic rod 11 is slidably connected with the third electric slide rail 22 through a sliding block 23, the electric telescopic rod 11 adopts a multi-section telescopic rod structure, a first infrared sensing probe 24 is arranged inside the slot 21, and a second infrared sensing probe 25 is arranged at one end of the inserting plate 12 away from the electric telescopic rod 11; utilize the counterpoint setting of first infrared inductive probe 24 and second infrared inductive probe 25, drive third electric slide rail 22 and electric telescopic handle 11 and carry out corresponding position control, inject picture peg 12 inside slot 21, reuse electric telescopic handle 11 and third electric slide rail 22's regulation take out the inside extrusion die 7 of first mould frame 6, place into second mould frame 8 inside can.

Further, as shown in fig. 2, both sides of the lower end surface of the bottom plate 1 are provided with first fans 26, both sides of the lower end surface of the top plate 5 are provided with second fans 27, the two first fans 26 are respectively located under the first mold frame 6 and the second mold frame 8, the two second fans 27 are respectively located over the first mold frame 6 and the second mold frame 8, air volume can be generated by utilizing the first fans 26 and the second fans 27, heat and cooling gas are blown to the surfaces of the first mold frame 6 and the second mold frame 8, and heating and cooling of the extrusion mold 7 can be accelerated.

Further, as shown in fig. 3, a heat transfer pipe 28 is disposed inside the steam pressurizing device 13, the heat transfer pipe 28 is connected to a plurality of heat transfer hoses 29, the plurality of heat transfer hoses 29 are respectively communicated with inlet ends of the copper pipes 20 inside the plurality of first mold frames 6, and the steam pressurizing device 13 transfers heat to the inside of the copper pipes 20 of the first mold frames 6 through the heat transfer pipe 28 and the plurality of heat transfer hoses 29.

Further, as shown in fig. 5 and 6, the cooling circulation structure 14 includes a first water tank 30, a second water tank 31 and a refrigeration compressor assembly 32, the compressor assembly 32 is communicated with the upper portion of the second water tank 31 through a refrigeration pipeline 33, the first water tank 30 is communicated with the second water tank 31 through a first water pump 36, and a second water pump 37 is arranged inside the first water tank 30;

a water pipe 35 is arranged on the inner surface of the inner side of the first water tank 30, the water pipe 35 is connected with a plurality of water delivery hoses 34, the plurality of water delivery hoses 34 are communicated with the open ends of the copper pipes 20 in the plurality of second mold frames 8, a drain pipe 38 is arranged above the second water tank 31, the drain pipe 38 is connected with a plurality of drain hoses 39, and the plurality of drain hoses 39 are communicated with the outlet ends of the copper pipes 20 in the plurality of second mold frames 8; the second water pump 37 is started, the water source in the first water tank 30 is conveyed into the copper pipe 20 in the second die frame 8 through the water conveying pipe 35 and the water conveying hose 34 by the second water pump 37, the extrusion die 7 is cooled by the cooling water source passing through the copper pipe 20, the cooling water passing through a circulation is discharged into the second water tank 31 through the water discharging hose 39 and the water discharging pipe 38, then the compressor assembly 32 is utilized, the cold air is conveyed into the second water tank 31 through the refrigerating pipeline 33, the cooling treatment of the water source is carried out, and the cooled water source is pumped into the first water tank 30 through the first water pump 36 to be reused.

Still further, as shown in fig. 5 and 6, a water injection pipe 40 is disposed on an upper end surface of the first water tank 30, the second water pump 37 is communicated with the water delivery pipe 35, the water injection pipe 40 is sealed by a sealing plug 41, the water injection pipe 40 is used for injecting water into the first water tank 30, and the sealing plug 41 is used for sealing the water injection pipe 40 to prevent foreign matters from entering.

A laminating method of a laminating machine for manufacturing a 5G communication module comprises the following steps:

s1: when laminating the modules, placing a plurality of groups of multilayer substances on a plurality of extrusion dies 7, then sliding the extrusion dies 7 into a plurality of first die frames 6, then starting a steam pressurizing device 13, inputting heat into the copper pipes 20 inside the plurality of first die frames 7 through a heat transmission pipe 28 and a plurality of heat transmission hoses 29, and heating the plurality of first die frames 7, thereby heating the extrusion dies 7 in the sliding grooves 17;

s2: then, the first electric slide rail 15 is opened, and a plurality of first die frames 6 are laminated, so that a plurality of layers of substances placed on the extrusion die 7 are heated and extruded, and heat passing through the inner part of the copper pipe 20 can be discharged from an outlet end;

s3: after the equipment is heated and extruded for a period of time, a plurality of first die frames 6 are separated by using the first electric slide rail 15, the third electric slide rail 22 and the electric telescopic rod 11 are driven to carry out corresponding position adjustment by using the alignment arrangement of the first infrared induction probe 24 and the second infrared induction probe 25, the inserting plate 12 is inserted into the slot 21, and then the extrusion dies 7 in the first die frames 6 are taken out by using the adjustment of the electric telescopic rod 11 and the third electric slide rail 22 and placed into the second die frame 8;

s4: when the extrusion mold 7 is clamped into the second mold frame 8 in a sliding manner, the second water pump 37 is started, the second water pump 37 is used for conveying a water source in the first water tank 30 to the copper pipe 20 in the second mold frame 8 through the water conveying pipe 35 and the water conveying hose 34, the second electric slide rail 16 is started at the same time, the second mold frames 8 are driven to be attached and extruded, the extrusion mold 7 is cooled by using a cooling water source passing through the copper pipe 20, the cooling water is discharged to the second water tank 31 through the water discharging hose 39 and the water discharging pipe 38 after passing through a circulation, then the compressor assembly 32 is used for conveying cold air to the second water tank 31 through the refrigerating pipeline 33, the water source is cooled, and the cooled water source is pumped into the first water tank 30 through the first water pump 36 for reuse.

As used in the specification and in the claims, certain terms are used to refer to particular components. As one skilled in the art will appreciate, manufacturers may refer to a component by different names. This specification and claims do not intend to distinguish between components that differ in name but not function. In the following description and in the claims, the terms "include" and "comprise" are used in an open-ended fashion, and thus should be interpreted to mean "include, but not limited to. "substantially" means within an acceptable error range, and a person skilled in the art can solve the technical problem within a certain error range to achieve the technical effect basically.

It should be noted that the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a good or system that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such good or system. Without further limitation, an element defined by the phrase "comprising one … …" does not exclude the presence of another identical element in a good or system comprising the element.

The foregoing description shows and describes several preferred embodiments of the invention, but as aforementioned, it is to be understood that the invention is not limited to the forms disclosed herein, and is not to be construed as excluding other embodiments, and that the invention is capable of use in various other combinations, modifications, and environments and is capable of changes within the scope of the inventive concept as expressed herein, commensurate with the above teachings, or the skill or knowledge of the relevant art. And that modifications and variations may be effected by those skilled in the art without departing from the spirit and scope of the invention as defined by the appended claims.

Claims (10)

1. A laminating machine for manufacturing a 5G communication module comprises a bottom plate (1), and is characterized in that a first baffle (2) and a second baffle (3) are respectively arranged on two sides of the upper end face of the bottom plate (1), a top plate (5) is arranged above the space between the first baffle (2) and the second baffle (3), and a partition plate (4) is vertically arranged in the middle of the upper end face of the bottom plate (1);

a plurality of first die frames (6) are arranged on the inner side surface of the first baffle (2) and one side surface of the partition plate (4) in a vertically sliding mode, an extrusion die (7) is arranged on each first die frame (6) in a sliding mode, and a plurality of second die frames (8) are arranged on the inner side surface of the second baffle (3) and the other side surface of the partition plate (4) in a vertically sliding mode;

a supporting plate (9) is arranged on the front side face of the bottom plate (1) in a sliding mode, a second supporting plate (10) is vertically arranged on one side, away from the bottom plate (1), of the upper end face of the supporting plate (9), an electric telescopic rod (11) is vertically arranged on the inner side face of the second supporting plate (10) in a sliding mode, an inserting plate (12) is arranged on the front end face of the electric telescopic rod (11), and the inserting plate (12) is used for inserting the extrusion die (7);

the back of the bottom plate (1) is provided with a steam pressurizing device (13) and a cooling circulating structure (14) respectively, the steam pressurizing device (13) is communicated with the inside of the first mold frame (6), and the cooling circulating structure (14) is communicated with the inside of the second mold frame (8).

2. The laminating machine for manufacturing the 5G communication module according to claim 1, wherein: first baffle (2) medial surface with the equal vertical first electronic slide rail of a plurality of (15) that is provided with in a side of baffle (4), first mould frame (6) with first electronic slide rail (15) sliding connection, second baffle (3) medial surface with the equal vertical electronic slide rail of second (16) that is provided with in another side of baffle (4), second mould frame (8) with electronic slide rail of second (16) sliding connection.

3. The laminating machine for manufacturing the 5G communication module according to claim 1, wherein: sliding grooves (17) are formed in the upper end faces of the first die frame (6) and the second die frame (8), sliding blocks (18) are arranged on two sides of each sliding groove (17), sliding grooves (19) which are connected with the sliding blocks (18) in a sliding mode are arranged on two sides of the extrusion die (7), copper pipes (20) which are arranged in a spiral mode are arranged inside the first die frame (6) and the second extrusion die (8), the inlet ends and the outlet ends of the copper pipes (20) protrude out of the side faces of the first die frame (6) and the second die frame (8), and inserting grooves (21) are formed in the front end face of the extrusion die (7).

4. The laminating machine for manufacturing the 5G communication module according to claim 3, wherein: the vertical third electric slide rail (22) that is provided with of medial surface of second backup pad (10), electric telescopic handle (11) through sliding block (23) with third electric slide rail (22) sliding connection, electric telescopic handle (11) adopt multistage formula telescopic link structure, slot (21) inside is provided with first infrared inductive probe (24), picture peg (12) are kept away from the one end of electric telescopic handle (11) is provided with second infrared inductive probe (25).

5. The laminating machine for manufacturing the 5G communication module according to claim 1, wherein: both sides of terminal surface all are provided with first fan (26) under bottom plate (1), the lower terminal surface both sides of roof (5) all are provided with second fan (27), two first fan (26) are in respectively under first mould frame (6) with second mould frame (8), two second fan (27) are in respectively directly over first mould frame (6) with second mould frame (8).

6. The laminating machine for manufacturing the 5G communication module according to claim 3, wherein: the inner side of the steam pressurizing device (13) is provided with a heat transfer pipe (28), the heat transfer pipe (28) is connected with a plurality of heat transfer hoses (29), and the heat transfer hoses (29) are respectively communicated with inlet ends of the copper pipes (20) in the first die frames (6).

7. The laminating machine for manufacturing the 5G communication module according to claim 6, wherein: the cooling circulation structure (14) comprises a first water tank (30), a second water tank (31) and a refrigeration compressor assembly (32), the compressor assembly (32) is communicated with the upper portion of the second water tank (31) through a refrigeration pipeline (33), the first water tank (30) is communicated with the second water tank (31) through a first water pump (36), and a second water pump (37) is arranged inside the first water tank (30).

8. The laminating machine for manufacturing the 5G communication module according to claim 7, wherein: the inner side of the first water tank (30) is provided with a water conveying pipe (35), the water conveying pipe (35) is connected with a plurality of water conveying hoses (34), the plurality of water conveying hoses (34) are communicated with the opening ends of the copper pipes (20) in the second die frame (8), a drain pipe (38) is arranged above the second water tank (31), the drain pipe (38) is connected with a plurality of drainage hoses (39), and the plurality of drainage hoses (39) are communicated with the outlet ends of the copper pipes (20) in the second die frame (8).

9. The laminating machine for manufacturing the 5G communication module according to claim 7, wherein: the upper end face of the first water tank (30) is provided with a water injection pipe (40), the second water pump (37) is communicated with the water delivery pipe (35), and the water injection pipe (40) is sealed through a sealing plug (41).

10. A laminating method of a laminating machine for manufacturing a 5G communication module is characterized in that: the method comprises the following steps:

s1: when the module is laminated, a plurality of groups of multilayer substances are placed on a plurality of extrusion dies (7), then the extrusion dies (7) are slid into a plurality of first die frames (6), then a steam pressurizing device (13) is started, heat is input into copper pipes (20) in the plurality of first die frames (7) through a heat transmission pipe (28) and a plurality of heat transmission hoses (29), and the plurality of first die frames (7) are heated, so that the extrusion dies (7) in a sliding groove (17) are heated;

s2: then, a first electric slide rail (15) is opened, a plurality of first die frames (6) are laminated, so that a plurality of layers of substances placed on the extrusion die (7) are heated and extruded, and heat passing through the inside of the copper pipe (20) is discharged from an outlet end;

s3: after equipment is heated and extruded for a period of time, the first electric slide rail (15) is used for separating a plurality of first die frames (6), the first infrared induction probe (24) and the second infrared induction probe (25) are used for aligning, the third electric slide rail (22) and the electric telescopic rod (11) are driven to carry out corresponding position adjustment, the inserting plate (12) is inserted into the inserting groove (21), and then the extrusion die (7) in the first die frames (6) are taken out and placed into the second die frame (8) by using the adjustment of the electric telescopic rod (11) and the third electric slide rail (22);

s4: work as extrusion tooling (7) slip card is gone into inside second mould frame (8), open second water pump (37), utilize second water pump (37) pass through raceway (35) and water delivery hose (34) with the inside water source of first water tank (30) and carry extremely inside second mould frame (8) in copper pipe (20), open second electric slide rail (16) simultaneously, drive a plurality of second mould frame (8) laminate the extrusion, utilize the process the inside cooling water source of copper pipe (20) will extrusion tooling (7) carry out cooling and temperature reduction and handle, and the cooling water through a circulation can discharge to inside second water tank (31) through drainage hose (39) and drain pipe (38), then utilize compressor assembly (32), carry air conditioning to inside second water tank (31) through refrigeration pipeline (33), carry out the cooling processing to the water source, the water source through cooling is taken out first water pump (36) and is taken out reuse in first water tank (30).

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