CN110696262A - Thin wall multi-cavity mould rapid prototyping equipment - Google Patents

Abstract

The invention relates to a forming device, in particular to a thin-wall multi-cavity die rapid forming device. The technical problem is as follows: the thin-wall multi-cavity mold rapid forming equipment can absorb heat in multiple stages, enables a solvent colloid to be cooled more quickly, saves a large amount of time, and does not influence subsequent working efficiency. The technical scheme of the invention is as follows: a thin-wall multi-cavity die rapid molding device comprises a mounting seat, a stamping die sleeve, a stamping block, a circulating pump, a heat dissipation water pipe, a heat conduction sleeve, a Stirling pump body, a moving sleeve, a moving rod, a moving piston and the like; and a stamping die sleeve which can enable the soluble material colloid to be placed is embedded in the middle of the top of the mounting seat. According to the invention, the cooling liquid is added into the heat dissipation water pipe, the circulating pump is started to enable the cooling liquid to continuously flow, and the cooling liquid can absorb heat generated when the stamping block carries out extrusion forming on the soluble colloid, so that the soluble colloid is cooled and formed more quickly, a large amount of time is saved, and the working efficiency is improved.

Description

Thin wall multi-cavity mould rapid prototyping equipment

Technical Field

The invention relates to a forming device, in particular to a thin-wall multi-cavity die rapid forming device.

Background

In the process of moulding plastics, need through the continuous extrusion of mould with the solute colloid, but when extrudeing the solute colloid, a large amount of heats can appear, then can the shaping after the heat on the messenger solute colloid disappears the cooling, people all directly place the solute colloid and make its natural cooling, because natural cooling's speed is slow, then need spend a large amount of time, and refrigerated time is long, lead to subsequent work efficiency to reduce, so people can directly cool off the shaping with special cooling arrangement to the solute colloid, so the cost that consumes is high.

Disclosure of Invention

In order to overcome the defects that the solvent colloid is placed and naturally cooled, because the natural cooling speed is slow, a large amount of time is needed, and the subsequent working efficiency is reduced because the cooling time is long, the technical problem is as follows: the thin-wall multi-cavity mold rapid forming equipment can absorb heat in multiple stages, enables a solvent colloid to be cooled more quickly, saves a large amount of time, and does not influence subsequent working efficiency.

The technical scheme of the invention is as follows: a thin-wall multi-cavity die rapid molding device comprises a mounting seat, a stamping die sleeve, a stamping block, a circulating pump, a heat-radiating water pipe, a heat-conducting sleeve, a Stirling pump body, a movable sleeve, a movable rod, a movable piston, a gas-moving piston, a first clamping sleeve, an energy dissipation device, a spring rod, a second clamping sleeve, a clamping rod, a connecting sleeve, a first one-way pipe, a second one-way pipe and a valve, wherein the stamping die sleeve capable of placing a soluble material colloid is embedded in the middle of the top of the mounting seat, the stamping block is arranged right above the stamping die sleeve and matched with the stamping die sleeve, the heat-radiating water pipe is arranged at the lower part in the mounting seat, the circulating pump capable of enabling cooling liquid to flow is arranged at the front part of the right side of the heat-radiating water pipe, the two connecting sleeves are connected at the right part of the rear side of the heat-radiating water, the rear end of the first one-way pipe penetrates through the right part of the rear side of the mounting seat, the middle part of the rear side of the right side connecting sleeve is connected with a second one-way pipe capable of discharging cooling liquid, the rear end of the second one-way pipe penetrates through the right part of the rear side of the mounting seat, valves are arranged on the first one-way pipe and the second one-way pipe, the front part of the outer left side of the cooling water pipe is connected with a heat conduction sleeve, the middle part of the left side of the heat conduction sleeve is connected with a Stirling pump body, the Stirling pump body is communicated with the heat conduction sleeve, the left end of the Stirling pump body penetrates through the front part of the left side of the mounting seat, a movable piston is arranged in the Stirling pump body in a sliding mode, the movable sleeve is arranged in the middle part of the left side of the Stirling pump body in an embedded mode, a movable rod is arranged in the, a first clamping sleeve is fixedly connected to the left side of the top of the moving rod, a spring rod is installed on the rear portion of the left side face of the installation seat, a second clamping sleeve is connected to the left end of the spring rod, a clamping rod is arranged in the second clamping sleeve, and the front end of the clamping rod is located in the first clamping sleeve and matched with the first clamping sleeve.

Furthermore, the energy consumption device comprises a horizontal pump body, an alloy piston and a compression spring, the horizontal pump body is installed on the outer left side face of the Stirling pump body, the alloy piston is arranged in a sliding mode in the horizontal pump body, the compression spring is connected between the left side face of the alloy piston and the inner left side face of the horizontal pump body, the left end of the moving rod is fixedly connected with the middle of the right side face of the alloy piston, openings with guiding effects are formed in the right portions of the front side and the rear side of the horizontal pump body, and the clamping rod is located in the openings.

Further comprises a first heat-conducting plate and a first heat-conducting rod, second heat-conducting plate, second heat-conducting rod and cooling tube, install first heat-conducting plate between upper portion in stamping die cover lower part and the mount pad, first heat-conducting plate left and right sides face lower part all is connected with the second heat-conducting rod, the cooling tube is installed to mount pad left and right sides face upper portion all embedded, left side cooling tube right side middle part and left side second heat-conducting rod left end fixed connection, right side cooling tube left side middle part and right side second heat-conducting rod right-hand member fixed connection, left side cooling tube left side upper portion and right side cooling tube right side upper portion all open the stock solution chamber that can make the coolant liquid place, first heat-conducting plate bottom is even spaced installs first heat-conducting rod, install the second heat-conducting plate between whole first heat-conducting rod bottoms, second heat-conducting plate bottom is even spaced opens there are a plurality of.

Furthermore, the heat dissipation water pipe comprises a plurality of buffer plates, wherein the plurality of buffer plates are uniformly arranged in the middle of the heat dissipation water pipe at intervals, a first lyophobic hole is formed in the middle of the inner side surface of each buffer plate, and a plurality of second lyophobic holes are formed in the buffer plates at uniform intervals in the circumferential direction.

Further, still including transparent plate and scale, open in mount pad trailing flank left side has the recess, installs the transparent plate between the recess left and right sides face rear side, and the vertical scale of installing in transparent plate leading flank left side, scale bottom and recess bottom fixed connection.

According to the invention, the cooling liquid is added into the heat dissipation water pipe, the circulating pump is started to enable the cooling liquid to continuously flow, the cooling liquid can absorb heat generated when the stamping block carries out extrusion forming on the soluble colloid, so that the soluble colloid is cooled and formed more quickly, a large amount of time is saved, the working efficiency is improved, the heat can be further absorbed and removed through the action of the first heat conduction plate and the liquid storage cavity, and the cooling efficiency of the soluble colloid is higher.

Drawings

Fig. 1 is a schematic front view of the present invention.

Fig. 2 is a schematic diagram of a partial top view structure of the present invention.

Fig. 3 is an enlarged schematic view of the structure of the present invention a.

Fig. 4 is a partial sectional structural schematic view of the present invention.

In the reference symbols: 1 mount pad, 2 stamping die cover, 3 punching press pieces, 4 circulating pumps, 5 heat dissipation water pipes, 6 heat conduction cover, 7 stirling pump body, 8 moving covers, 9 movable rod, 10 moving piston, 11 gas moving piston, 12 first cutting ferrule, 13 energy dissipation device, 131 horizontal pump body, 132 alloy piston, 133 compression spring, 134 opening, 14 spring rod, 15 second cutting ferrule, 16 card pole, 17 adapter sleeve, 18 first check tube, 19 second check tube, 20 valve, 21 first heat-conducting plate, 22 first heat-conducting rod, 23 second heat-conducting plate, 24 arc-shaped groove, 25 second heat-conducting rod, 26 radiating pipe, 27 stock solution chamber, 28 buffer plate, 29 first lyophobic hole, 30 second lyophobic hole, 31 recess, 32 transparent plate, 33 scale.

Detailed Description

The invention is described in detail below with reference to the figures and the embodiments.

Example 1

A thin-wall multi-cavity die rapid forming device is shown in figures 1-3 and comprises a mounting seat 1, a stamping die sleeve 2, a stamping block 3, a circulating pump 4, a heat-radiating water pipe 5, a heat-conducting sleeve 6, a Stirling pump body 7, a moving sleeve 8, a moving rod 9, a moving piston 10, a gas-moving piston 11, a first cutting sleeve 12, an energy consumption device 13, a spring rod 14, a second cutting sleeve 15, a clamping rod 16, a connecting sleeve 17, a first one-way pipe 18, a second one-way pipe 19 and a valve 20, wherein the stamping die sleeve 2 capable of placing a soluble material colloid is embedded in the middle of the top of the mounting seat 1, the stamping block 3 is arranged right above the stamping die sleeve 2, the stamping block 3 is matched with the stamping die sleeve 2, the heat-radiating water pipe 5 is arranged at the inner lower part of the mounting seat 1, the circulating pump 4 capable of flowing a cooling liquid is arranged at the front part of the right side of, the connecting sleeve 17 is communicated with the interior of the heat-radiating water pipe 5, the middle part of the rear side of the left connecting sleeve 17 is connected with a first one-way pipe 18 which can enable cooling liquid to be added, the rear end of the first one-way pipe 18 penetrates through the right part of the rear side of the mounting seat 1, the middle part of the rear side of the right connecting sleeve 17 is connected with a second one-way pipe 19 which can enable the cooling liquid to be discharged, the rear end of the second one-way pipe 19 penetrates through the right part of the rear side of the mounting seat 1, the first one-way pipe 18 and the second one-way pipe 19 are both provided with valves 20, the front part of the left side outside the heat-radiating water pipe 5 is connected with a heat-conducting sleeve 6, the middle part of the left side of the heat-conducting sleeve 6 is connected with a Stirling pump body 7, the heat-conducting sleeve 6 is connected with the Stirling pump body 7 in a welding connection mode, the middle of the left side of the Stirling pump body 7 is embedded to be installed with a movable sleeve 8, the movable sleeve 8 is internally provided with a movable rod 9 in a sliding mode, the right end of the movable rod 9 penetrates through the middle of a movable piston 10 and is provided with a gas moving piston 11, the movable rod 9 is connected with the gas moving piston 11 through a welding connection mode, the movable rod 9 is fixedly connected with the movable piston 10, the outer left side of the Stirling pump body 7 is provided with an energy dissipation device 13, the energy dissipation device 13 is connected with the left end of the movable rod 9, the left side of the top of the movable rod 9 is fixedly connected with a first clamping sleeve 12, the spring rod 14 is installed at the rear part of the left side of the mounting seat 1, the mounting seat 1 is connected with the spring rod 14 through a welding connection mode, the left end of the spring rod 14 is connected with a second clamping.

Example 2

A thin-wall multi-cavity die rapid forming device is shown in figures 1-3 and comprises a mounting seat 1, a stamping die sleeve 2, a stamping block 3, a circulating pump 4, a heat-radiating water pipe 5, a heat-conducting sleeve 6, a Stirling pump body 7, a moving sleeve 8, a moving rod 9, a moving piston 10, a gas-moving piston 11, a first cutting sleeve 12, an energy consumption device 13, a spring rod 14, a second cutting sleeve 15, a clamping rod 16, a connecting sleeve 17, a first one-way pipe 18, a second one-way pipe 19 and a valve 20, wherein the stamping die sleeve 2 capable of placing a soluble material colloid is embedded in the middle of the top of the mounting seat 1, the stamping block 3 is arranged right above the stamping die sleeve 2, the stamping block 3 is matched with the stamping die sleeve 2, the heat-radiating water pipe 5 is arranged at the inner lower part of the mounting seat 1, the circulating pump 4 capable of flowing a cooling liquid is arranged at the front part of the right side of, the connecting sleeve 17 is communicated with the interior of the heat-radiating water pipe 5, the middle part of the rear side of the left connecting sleeve 17 is connected with a first one-way pipe 18 which can enable cooling liquid to be added, the rear end of the first one-way pipe 18 penetrates through the right part of the rear side of the mounting seat 1, the middle part of the rear side of the right connecting sleeve 17 is connected with a second one-way pipe 19 which can enable the cooling liquid to be discharged, the rear end of the second one-way pipe 19 penetrates through the right part of the rear side of the mounting seat 1, valves 20 are arranged on the first one-way pipe 18 and the second one-way pipe 19, the front part of the left side outside the heat-radiating water pipe 5 is connected with a heat-conducting sleeve 6, the middle part of the left side of the heat-conducting sleeve 6 is connected with a Stirling pump body 7, the Stirling pump body 7 is communicated with the interior of the heat-conducting sleeve 6, the, the movable rod 9 is arranged in the movable sleeve 8 in a sliding mode, the middle of the movable piston 10 is penetrated through the right end of the movable rod 9, the air moving piston 11 is arranged, the movable rod 9 is fixedly connected with the movable piston 10, the energy dissipation device 13 is arranged on the outer left side face of the Stirling pump body 7, the energy dissipation device 13 is connected with the left end of the movable rod 9, a first clamping sleeve 12 is fixedly connected to the left side of the top of the movable rod 9, a spring rod 14 is installed on the rear portion of the left side face of the mounting seat 1, the left end of the spring rod 14 is connected with a second clamping sleeve 15, a clamping rod 16 is arranged in the second clamping sleeve 15, and.

The energy consumption device 13 comprises a horizontal pump body 131, an alloy piston 132 and a compression spring 133, the horizontal pump body 131 is installed on the outer left side face of the Stirling pump body 7, the Stirling pump body 7 is connected with the horizontal pump body 131 in a welding connection mode, the alloy piston 132 is arranged in the horizontal pump body 131 in a sliding mode, the compression spring 133 is connected between the left side face of the alloy piston 132 and the inner left side face of the horizontal pump body 131, the left end of the movable rod 9 is fixedly connected with the middle of the right side face of the alloy piston 132, the movable rod 9 is connected with the alloy piston 132 in a welding connection mode, openings 134 with guiding functions are formed in the right portions of the front side and the rear side of the horizontal pump body 131.

Example 3

A thin-wall multi-cavity die rapid forming device is shown in figures 1-3 and comprises a mounting seat 1, a stamping die sleeve 2, a stamping block 3, a circulating pump 4, a heat-radiating water pipe 5, a heat-conducting sleeve 6, a Stirling pump body 7, a moving sleeve 8, a moving rod 9, a moving piston 10, a gas-moving piston 11, a first cutting sleeve 12, an energy consumption device 13, a spring rod 14, a second cutting sleeve 15, a clamping rod 16, a connecting sleeve 17, a first one-way pipe 18, a second one-way pipe 19 and a valve 20, wherein the stamping die sleeve 2 capable of placing a soluble material colloid is embedded in the middle of the top of the mounting seat 1, the stamping block 3 is arranged right above the stamping die sleeve 2, the stamping block 3 is matched with the stamping die sleeve 2, the heat-radiating water pipe 5 is arranged at the inner lower part of the mounting seat 1, the circulating pump 4 capable of flowing a cooling liquid is arranged at the front part of the right side of, the connecting sleeve 17 is communicated with the interior of the heat-radiating water pipe 5, the middle part of the rear side of the left connecting sleeve 17 is connected with a first one-way pipe 18 which can enable cooling liquid to be added, the rear end of the first one-way pipe 18 penetrates through the right part of the rear side of the mounting seat 1, the middle part of the rear side of the right connecting sleeve 17 is connected with a second one-way pipe 19 which can enable the cooling liquid to be discharged, the rear end of the second one-way pipe 19 penetrates through the right part of the rear side of the mounting seat 1, valves 20 are arranged on the first one-way pipe 18 and the second one-way pipe 19, the front part of the left side outside the heat-radiating water pipe 5 is connected with a heat-conducting sleeve 6, the middle part of the left side of the heat-conducting sleeve 6 is connected with a Stirling pump body 7, the Stirling pump body 7 is communicated with the interior of the heat-conducting sleeve 6, the, the movable rod 9 is arranged in the movable sleeve 8 in a sliding mode, the middle of the movable piston 10 is penetrated through the right end of the movable rod 9, the air moving piston 11 is arranged, the movable rod 9 is fixedly connected with the movable piston 10, the energy dissipation device 13 is arranged on the outer left side face of the Stirling pump body 7, the energy dissipation device 13 is connected with the left end of the movable rod 9, a first clamping sleeve 12 is fixedly connected to the left side of the top of the movable rod 9, a spring rod 14 is installed on the rear portion of the left side face of the mounting seat 1, the left end of the spring rod 14 is connected with a second clamping sleeve 15, a clamping rod 16 is arranged in the second clamping sleeve 15, and.

The energy consumption device 13 comprises a horizontal pump body 131, an alloy piston 132 and a compression spring 133, the horizontal pump body 131 is installed on the outer left side face of the Stirling pump body 7, the alloy piston 132 is arranged in the horizontal pump body 131 in a sliding mode, the compression spring 133 is connected between the left side face of the alloy piston 132 and the inner left side face of the horizontal pump body 131, the left end of the movable rod 9 is fixedly connected with the middle of the right side face of the alloy piston 132, openings 134 which play a role in guiding are formed in the right portions of the front side face and the rear side face of the horizontal pump body 131, and the clamping rod.

The heat dissipation device further comprises a first heat conduction plate 21, a first heat conduction rod 22, a second heat conduction plate 23, a second heat conduction rod 25 and a heat dissipation pipe 26, wherein the first heat conduction plate 21 is installed between the lower portion in the stamping die sleeve 2 and the upper portion in the mounting seat 1, the lower portions of the left side surface and the right side surface of the first heat conduction plate 21 are connected with the second heat conduction rod 25, the first heat conduction plate 21 is connected with the second heat conduction rod 25 in a welding connection mode, the heat dissipation pipe 26 is installed on the upper portions of the left side surface and the right side surface of the mounting seat 1 in an embedded mode, the middle portion of the right side of the left side heat dissipation pipe 26 is fixedly connected with the left end of the left side second heat conduction rod 25, the middle portion of the left side of the right side heat dissipation pipe 26 is fixedly connected with the right end of the right side second heat conduction rod 25, liquid storage cavities 27 capable of containing cooling liquid are formed in the upper portions of, the second heat conducting plate 23 is arranged between the bottom ends of all the first heat conducting rods 22, a plurality of arc-shaped grooves 24 are uniformly arranged at the bottom of the second heat conducting plate 23 at intervals, and the upper part of the heat radiating water pipe 5 is positioned in the arc-shaped grooves 24 and is contacted with the heat radiating water pipe.

Example 4

A thin-wall multi-cavity die rapid forming device is shown in figures 1-4 and comprises a mounting seat 1, a stamping die sleeve 2, a stamping block 3, a circulating pump 4, a heat-radiating water pipe 5, a heat-conducting sleeve 6, a Stirling pump body 7, a moving sleeve 8, a moving rod 9, a moving piston 10, a gas-moving piston 11, a first cutting sleeve 12, an energy consumption device 13, a spring rod 14, a second cutting sleeve 15, a clamping rod 16, a connecting sleeve 17, a first one-way pipe 18, a second one-way pipe 19 and a valve 20, wherein the stamping die sleeve 2 capable of placing a soluble material colloid is embedded in the middle of the top of the mounting seat 1, the stamping block 3 is arranged right above the stamping die sleeve 2, the stamping block 3 is matched with the stamping die sleeve 2, the heat-radiating water pipe 5 is arranged at the inner lower part of the mounting seat 1, the circulating pump 4 capable of flowing a cooling liquid is arranged at the front part of the right side of, the connecting sleeve 17 is communicated with the interior of the heat-radiating water pipe 5, the middle part of the rear side of the left connecting sleeve 17 is connected with a first one-way pipe 18 which can enable cooling liquid to be added, the rear end of the first one-way pipe 18 penetrates through the right part of the rear side of the mounting seat 1, the middle part of the rear side of the right connecting sleeve 17 is connected with a second one-way pipe 19 which can enable the cooling liquid to be discharged, the rear end of the second one-way pipe 19 penetrates through the right part of the rear side of the mounting seat 1, valves 20 are arranged on the first one-way pipe 18 and the second one-way pipe 19, the front part of the left side outside the heat-radiating water pipe 5 is connected with a heat-conducting sleeve 6, the middle part of the left side of the heat-conducting sleeve 6 is connected with a Stirling pump body 7, the Stirling pump body 7 is communicated with the interior of the heat-conducting sleeve 6, the, the movable rod 9 is arranged in the movable sleeve 8 in a sliding mode, the middle of the movable piston 10 is penetrated through the right end of the movable rod 9, the air moving piston 11 is arranged, the movable rod 9 is fixedly connected with the movable piston 10, the energy dissipation device 13 is arranged on the outer left side face of the Stirling pump body 7, the energy dissipation device 13 is connected with the left end of the movable rod 9, a first clamping sleeve 12 is fixedly connected to the left side of the top of the movable rod 9, a spring rod 14 is installed on the rear portion of the left side face of the mounting seat 1, the left end of the spring rod 14 is connected with a second clamping sleeve 15, a clamping rod 16 is arranged in the second clamping sleeve 15, and.

The energy consumption device 13 comprises a horizontal pump body 131, an alloy piston 132 and a compression spring 133, the horizontal pump body 131 is installed on the outer left side face of the Stirling pump body 7, the alloy piston 132 is arranged in the horizontal pump body 131 in a sliding mode, the compression spring 133 is connected between the left side face of the alloy piston 132 and the inner left side face of the horizontal pump body 131, the left end of the movable rod 9 is fixedly connected with the middle of the right side face of the alloy piston 132, openings 134 which play a role in guiding are formed in the right portions of the front side face and the rear side face of the horizontal pump body 131, and the clamping rod.

The heat-conducting plate comprises a first heat-conducting plate 21, a first heat-conducting rod 22, a second heat-conducting plate 23, a second heat-conducting rod 25 and a heat-radiating pipe 26, wherein the first heat-conducting plate 21 is arranged between the inner lower part of the stamping die sleeve 2 and the inner upper part of the mounting seat 1, the lower parts of the left side surface and the right side surface of the first heat-conducting plate 21 are connected with the second heat-conducting rod 25, the heat-radiating pipe 26 is arranged on the upper parts of the left side surface and the right side surface of the mounting seat 1 in an embedded manner, the right middle part of the left side heat-radiating pipe 26 is fixedly connected with the left end of the left side second heat-conducting rod 25, the left middle part of the right side heat-radiating pipe 26 is fixedly connected with the right end of the right side second heat-conducting rod 25, liquid storage cavities 27 capable of containing cooling liquid are formed in the left upper part of the left side of the left, the upper part of the heat radiation water pipe 5 is positioned in the arc-shaped groove 24 and is contacted with the same.

Still including buffer plate 28, the even spaced a plurality of buffer plates 28 of installing in middle part in the heat dissipation water pipe 5, heat dissipation water pipe 5 is connected with buffer plate 28 through welded connection's mode, and it has first lyophobic hole 29 to open at 28 medial surface middle parts of buffer plate, and the even spaced division of circumference has a plurality of second lyophobic holes 30 on the buffer plate 28.

Example 5

A thin-wall multi-cavity die rapid forming device is shown in figures 1-4 and comprises a mounting seat 1, a stamping die sleeve 2, a stamping block 3, a circulating pump 4, a heat-radiating water pipe 5, a heat-conducting sleeve 6, a Stirling pump body 7, a moving sleeve 8, a moving rod 9, a moving piston 10, a gas-moving piston 11, a first cutting sleeve 12, an energy consumption device 13, a spring rod 14, a second cutting sleeve 15, a clamping rod 16, a connecting sleeve 17, a first one-way pipe 18, a second one-way pipe 19 and a valve 20, wherein the stamping die sleeve 2 capable of placing a soluble material colloid is embedded in the middle of the top of the mounting seat 1, the stamping block 3 is arranged right above the stamping die sleeve 2, the stamping block 3 is matched with the stamping die sleeve 2, the heat-radiating water pipe 5 is arranged at the inner lower part of the mounting seat 1, the circulating pump 4 capable of flowing a cooling liquid is arranged at the front part of the right side of, the connecting sleeve 17 is communicated with the interior of the heat-radiating water pipe 5, the middle part of the rear side of the left connecting sleeve 17 is connected with a first one-way pipe 18 which can enable cooling liquid to be added, the rear end of the first one-way pipe 18 penetrates through the right part of the rear side of the mounting seat 1, the middle part of the rear side of the right connecting sleeve 17 is connected with a second one-way pipe 19 which can enable the cooling liquid to be discharged, the rear end of the second one-way pipe 19 penetrates through the right part of the rear side of the mounting seat 1, valves 20 are arranged on the first one-way pipe 18 and the second one-way pipe 19, the front part of the left side outside the heat-radiating water pipe 5 is connected with a heat-conducting sleeve 6, the middle part of the left side of the heat-conducting sleeve 6 is connected with a Stirling pump body 7, the Stirling pump body 7 is communicated with the interior of the heat-conducting sleeve 6, the, the movable rod 9 is arranged in the movable sleeve 8 in a sliding mode, the middle of the movable piston 10 is penetrated through the right end of the movable rod 9, the air moving piston 11 is arranged, the movable rod 9 is fixedly connected with the movable piston 10, the energy dissipation device 13 is arranged on the outer left side face of the Stirling pump body 7, the energy dissipation device 13 is connected with the left end of the movable rod 9, a first clamping sleeve 12 is fixedly connected to the left side of the top of the movable rod 9, a spring rod 14 is installed on the rear portion of the left side face of the mounting seat 1, the left end of the spring rod 14 is connected with a second clamping sleeve 15, a clamping rod 16 is arranged in the second clamping sleeve 15, and.

The energy consumption device 13 comprises a horizontal pump body 131, an alloy piston 132 and a compression spring 133, the horizontal pump body 131 is installed on the outer left side face of the Stirling pump body 7, the alloy piston 132 is arranged in the horizontal pump body 131 in a sliding mode, the compression spring 133 is connected between the left side face of the alloy piston 132 and the inner left side face of the horizontal pump body 131, the left end of the movable rod 9 is fixedly connected with the middle of the right side face of the alloy piston 132, openings 134 which play a role in guiding are formed in the right portions of the front side face and the rear side face of the horizontal pump body 131, and the clamping rod.

The heat-conducting plate comprises a first heat-conducting plate 21, a first heat-conducting rod 22, a second heat-conducting plate 23, a second heat-conducting rod 25 and a heat-radiating pipe 26, wherein the first heat-conducting plate 21 is arranged between the inner lower part of the stamping die sleeve 2 and the inner upper part of the mounting seat 1, the lower parts of the left side surface and the right side surface of the first heat-conducting plate 21 are connected with the second heat-conducting rod 25, the heat-radiating pipe 26 is arranged on the upper parts of the left side surface and the right side surface of the mounting seat 1 in an embedded manner, the right middle part of the left side heat-radiating pipe 26 is fixedly connected with the left end of the left side second heat-conducting rod 25, the left middle part of the right side heat-radiating pipe 26 is fixedly connected with the right end of the right side second heat-conducting rod 25, liquid storage cavities 27 capable of containing cooling liquid are formed in the left upper part of the left side of the left, the upper part of the heat radiation water pipe 5 is positioned in the arc-shaped groove 24 and is contacted with the same.

Still including the buffer board 28, the even spaced a plurality of buffer boards 28 of installing in middle part in the heat dissipation water pipe 5, the medial surface middle part of buffer board 28 is opened has first lyophobic hole 29, and the even spaced division of circumference has a plurality of second lyophobic holes 30 on the buffer board 28.

Still including transparent plate 32 and scale 33, open on 1 trailing flank left side of mount pad has recess 31, installs transparent plate 32 between the recess 31 left and right sides face rear side, and the vertical scale 33 of installing in transparent plate 32 leading flank left side, transparent plate 32 are connected with scale 33 through welded connection's mode, and scale 33 bottom and recess 31 bottom fixed connection.

Firstly, an operator installs a stamping block 3 on a driving device, opens a left valve 20, adds a proper amount of cooling liquid into a heat-radiating water pipe 5 through a first one-way pipe 18, closes the left valve 20, pours a solvent colloid into a stamping die sleeve 2, and then starts the driving device, the driving device drives the stamping block 3 to move up and down, when the stamping block 3 moves down, the stamping block 3 extrudes the solvent colloid in the stamping die sleeve 2, and then the solvent colloid is slowly formed through the stamping die sleeve 2, the solvent colloid generates a large amount of heat in the extrusion process, so that the stamping die sleeve 2 becomes hot, a circulating pump 4 can be started, the circulating pump 4 operates to drive the cooling liquid in the heat-radiating water pipe 5 to flow, the cooling liquid flows to absorb the heat of the stamping die sleeve 2 through the heat-radiating water pipe 5, and further absorbs the heat in the solvent colloid, the sol is slowly cooled down, so that the sol is quickly formed, the sol does not need to be naturally cooled, the time is saved, the working efficiency is improved, along with the continuous heat absorption of cooling liquid through the heat dissipation water pipe 5, heat is discharged into the Stirling pump body 7 to drive the movable piston 10 to move leftwards, the movable piston 10 moves leftwards to drive the movable rod 9 to move leftwards, the movable rod 9 moves leftwards to drive the air moving piston 11 to move leftwards, meanwhile, the movable rod 9 also drives the energy consumption device 13 to operate, so that the heat is gradually lost, the movable rod 9 also drives the clamping rod 16 to move leftwards through the first clamping sleeve 12, the clamping rod 16 moves leftwards to drive the second clamping sleeve 15 to move leftwards, the spring rod 14 is stretched, when the heat is completely consumed, the gas is contracted, the cold gas pushes the air moving piston 11 to move rightwards, the air moving piston 11 drives the movable rod 9 to move rightwards, due to the action of the spring rod 14, the second clamping sleeve 15 moves rightwards to drive the clamping rod 16 to move rightwards for resetting, the clamping rod 16 drives the moving rod 9 to move rightwards for resetting through the first clamping sleeve 12, the moving piston 10 is further driven to move rightwards for resetting, meanwhile, the energy dissipation device 13 is operated and reset to enable the moving piston 10 to better reset through the moving rod 9, and the operation is repeated, so that heat in the heat dissipation water pipe 5 can be continuously consumed, and the cooling liquid can better absorb the heat. After the material dissolving colloid is formed, the driving device can be closed, the punching block 3 stops moving up and down, and the circulating pump 4 is closed, so that the formed product can be taken out from the punching die sleeve 2. When the coolant needs to be replaced for a long time, the right valve 20 can be opened, the coolant in the heat dissipation water pipe 5 is poured out through the second one-way pipe 19 by moving the mounting base 1, after the coolant is poured out, the right valve 20 is closed, the left valve 20 is opened, the coolant is added into the heat dissipation water pipe 5 through the first one-way pipe 18, and the left valve 20 is closed.

When heat is discharged into the Stirling pump body 7 to push the movable piston 10 to move leftwards, the movable rod 9 moves leftwards to drive the alloy piston 132 to move leftwards, the compression spring 133 compresses, and the heat is continuously consumed, after the heat is consumed, the alloy piston 132 moves rightwards to drive the movable rod 9 to move rightwards due to the action of the compression spring 133, so that the movable piston 10 and the gas moving piston 11 are driven to move rightwards to reset, and the heat discharged into the Stirling pump body 7 can be continuously consumed after the heat is repeatedly consumed.

At first in the operating personnel pours the coolant liquid into stock solution chamber 27, and then when punching press piece 3 reciprocated to extrude the solute colloid and make its shaping, the heat on stamping die cover 2 and the solute colloid still conducts on first heat-conducting plate 21, the heat conduction on first heat-conducting plate 21 is on second heat-conducting rod 25, and then the coolant liquid in the stock solution chamber 27 then absorbs the heat on second heat-conducting rod 25 through cooling tube 26, just also make the disappearance of the heat on first heat-conducting plate 21 more fast, then the faster messenger solute colloid cools off, and simultaneously, first heat-conducting plate 21 still conducts the heat on second heat-conducting plate 23 through first heat-conducting rod 22, the coolant liquid in the condenser tube 5 then absorbs the heat on second heat-conducting plate 23. Therefore, the heat can disappear more quickly, and the sol is cooled and formed more quickly.

When the circulating pump 4 makes the coolant of the heat radiation water pipe 5 flow back and forth, the coolant contacts the buffer plate 28, the buffer plate 28 buffers the coolant, and meanwhile, part of the coolant passes through the first lyophobic hole 29 and the second lyophobic hole 30 to cause waves. Therefore, the using effect of the cooling liquid can be better.

When the operator adds the coolant into the heat-dissipating water pipe 5 through the first check pipe 18, the operator can see the coolant in the heat-dissipating water pipe 5 through the transparent plate 32 and know the amount of the coolant in the heat-dissipating water pipe 5 through the scale 33, and when the amount of the coolant in the heat-dissipating water pipe 5 reaches the required amount of the coolant, the addition of the coolant is stopped. Therefore, the operator can know the amount of the cooling liquid in the heat dissipation water pipe 5 more clearly, and the increase of the cooling liquid is avoided.

The above description is only for the specific embodiments of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art can easily conceive of the changes or substitutions within the technical scope of the present invention, and all the changes or substitutions should be covered within the scope of the present invention. Therefore, the protection scope of the present invention shall be subject to the protection scope of the claims.

Claims (5)

1. The utility model provides a thin wall multi-cavity mold rapid prototyping equipment, including the mount pad, the stamping die cover, the punching press piece, the circulating pump, heat dissipation water pipe and heat conduction cover, the embedded stamping die cover that can make the solute colloid place of installing in the middle of the mount pad top, be equipped with the punching press piece directly over the stamping die cover, punching press piece and stamping die cover cooperation, heat dissipation water pipe is installed to the lower part in the mount pad, heat dissipation water pipe right side front-mounted has the circulating pump that can make the coolant liquid flow, heat dissipation water pipe outside left side front connection has heat conduction cover, its characterized in that: the Stirling engine further comprises a Stirling pump body, a moving sleeve, a moving rod, a moving piston, an air moving piston, a first clamping sleeve, an energy consumption device, a spring rod, a second clamping sleeve, a clamping rod, a connecting sleeve, a first one-way pipe, a second one-way pipe and valves, wherein the right part of the rear side of the radiating water pipe is connected with the two connecting sleeves, the connecting sleeves are communicated with the radiating water pipe, the middle part of the rear side of the left connecting sleeve is connected with the first one-way pipe capable of adding cooling liquid, the rear end of the first one-way pipe penetrates through the right part of the rear side of the mounting seat, the middle part of the rear side of the right connecting sleeve is connected with the second one-way pipe capable of discharging the cooling liquid, the rear end of the second one-way pipe penetrates through the right part of the rear side of the mounting seat, the valves are arranged on the first one-way pipe and the second one-way pipe, the middle part, the movable piston is in sliding fit with the Stirling pump body, the middle of the left side of the Stirling pump body is embedded to be provided with a movable sleeve, a movable rod is arranged in the movable sleeve in a sliding mode, the right end of the movable rod penetrates through the middle of the movable piston to be provided with a gas moving piston, the movable rod is fixedly connected with the movable piston, the left side face of the outer side of the Stirling pump body is provided with an energy dissipation device, the energy dissipation device is connected with the left end of the movable rod, a first clamping sleeve is fixedly connected to the left side of the top of the movable rod, a spring rod is arranged at the rear part of the left side face of the mounting seat, the left end.

2. The thin-walled multi-cavity mold rapid prototyping apparatus of claim 1, wherein: the energy consumption device comprises a horizontal pump body, an alloy piston and a compression spring, the horizontal pump body is installed on the outer left side face of the Stirling pump body, the alloy piston is arranged in the horizontal pump body in a sliding mode, the compression spring is connected between the left side face of the alloy piston and the inner left side face of the horizontal pump body, the left end of the movable rod is fixedly connected with the middle of the right side face of the alloy piston, openings with guiding effects are formed in the right portions of the front side and the rear side of the horizontal pump body, and the clamping rod is located in.

3. The thin-walled multi-cavity mold rapid prototyping apparatus of claim 2, wherein: also comprises a first heat conducting plate and a first heat conducting rod, second heat-conducting plate, second heat-conducting rod and cooling tube, install first heat-conducting plate between upper portion in stamping die cover lower part and the mount pad, first heat-conducting plate left and right sides face lower part all is connected with the second heat-conducting rod, the cooling tube is installed to mount pad left and right sides face upper portion all embedded, left side cooling tube right side middle part and left side second heat-conducting rod left end fixed connection, right side cooling tube left side middle part and right side second heat-conducting rod right-hand member fixed connection, left side cooling tube left side upper portion and right side cooling tube right side upper portion all open the stock solution chamber that can make the coolant liquid place, first heat-conducting plate bottom is even spaced installs first heat-conducting rod, install the second heat-conducting plate between whole first heat-conducting rod bottoms, second heat-conducting plate bottom is even spaced opens there are a plurality of.

4. The thin-walled multi-cavity mold rapid prototyping apparatus of claim 3, wherein: the heat dissipation water pipe is characterized by further comprising a plurality of buffer plates, wherein the plurality of buffer plates are uniformly arranged in the middle of the heat dissipation water pipe at intervals, a first liquid dredging hole is formed in the middle of the inner side surface of each buffer plate, and a plurality of second liquid dredging holes are formed in the buffer plates at intervals in the circumferential direction.

5. The thin-walled multi-cavity mold rapid prototyping apparatus of claim 4, wherein: still including transparent plate and scale, the mount pad trailing flank left side is opened flutedly, installs the transparent plate between the recess left and right sides face rear side, and the vertical scale of installing in transparent plate leading flank left side, scale bottom and recess bottom fixed connection.

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