CN219171609U - High-temperature die temperature machine based on indirect heating of water - Google Patents

Abstract

The utility model provides a high-temperature die temperature machine based on indirect heating of water, which relates to the technical field of high-temperature die temperature machines and comprises a shell component and a heat conduction component, wherein one end of the interior of the shell component is provided with a water supplementing component assembled by bolts, the output end of the water supplementing component is connected with a heating reflux mechanism connected with the shell component by bolts, the output end of the heating reflux mechanism is connected with a split sleeve, and one side of the split sleeve is provided with the heat conduction component connected with the heating reflux mechanism by bolts; the utility model mainly utilizes the flow diversion sleeve to open the liquid valve block, and then inputs the liquid valve block into the liquid diversion seat through the flow guide pipe arranged on the heat conduction assembly, under the interaction of the liquid diversion seat and the liquid diversion pipe, the heat generated by the water body is conducted into the plug-in block by adopting the fin group, and the heat of the water body is indirectly led into the mould through the heat conduction block and the slot seat, and the heat of the water body is not in contact heating between the water bodies, so that a great deal of loss of the water body is not caused, and the service life of the equipment is prolonged.

Description

High-temperature die temperature machine based on indirect heating of water

Technical Field

The utility model relates to the technical field of high-temperature die temperature machines, in particular to a high-temperature die temperature machine based on indirect heating of water.

Background

Gao Wenmo temperature machine, also called high temperature mould temperature controller, is widely used in the temperature control industry of injection mould, and consists of a water tank, a heating system, a power transmission system, a temperature sensor and other devices, and in normal circumstances, a pump in the power transmission system makes the hot fluid reach the mould from the water tank with built-in heater, and then returns from the mould to the water tank.

When the existing high-temperature die temperature machine is used, the heated water body is generally output to a die, after the released heat is preheated, the cooled water body is returned to a heating area for reheating, and the preheating effect is realized, as disclosed in application number CN202022927920.1, the high-temperature die temperature machine based on indirect heating of water comprises a machine body, a heating water tank is fixedly arranged at the bottom of the inner wall of the machine body, and a plurality of telescopic rods are fixedly arranged at the bottom of the inner wall of the heating water tank; however, in the above technology, the water body is directly input into the mold for preheating, however, the direct preheating of the water is easy to consume a large amount of water body, and the material attached to the water body is easy to damage the heating area of the water body, so the utility model provides a high-temperature mold temperature machine based on indirect heating of the water to solve the problems in the prior art.

Disclosure of Invention

According to the high-temperature die temperature machine based on water indirect heating, after the liquid valve block is opened by the diversion sleeve, the high-temperature die temperature machine based on water indirect heating is input to the liquid separation seat through the diversion pipe arranged on the heat conduction assembly, heat generated by the water body is conducted into the plug-in block through the fin group under the interaction of the liquid separation seat and the liquid separation pipe, and the heat of the water body is indirectly conducted into the die through the heat conduction block and the slot seat, so that a large amount of water body loss is not caused due to the fact that the heat is not heated through contact between the water bodies, and the service life of equipment is prolonged.

In order to achieve the purpose of the utility model, the utility model is realized by the following technical scheme: the high-temperature die temperature machine based on indirect heating of water comprises a shell component and a heat conduction component, wherein a water supplementing component assembled by a bolt is arranged at one end of the interior of the shell component, the output end of the water supplementing component is connected with a heating reflux mechanism connected with the shell component by the bolt, the output end of the heating reflux mechanism is connected with a flow dividing sleeve, and one side of the flow dividing sleeve is provided with the heat conduction component connected with the heating reflux mechanism by the bolt;

the heat conduction assembly comprises a lifting frame, a clamping seat, a guide pipe, a liquid separation seat, a liquid separation pipe, a fin group, a plug-in block, a heat conduction block, a bolt connecting plate, a slot seat and a water return pipe, wherein the clamping seat is connected with the top side of the heating reflux mechanism through a lifting frame bolt, one side of the clamping seat is provided with the guide pipe which is connected with a liquid separation sleeve in a sleeved mode, the input end of the guide pipe penetrates through the clamping seat to be connected with the liquid separation seat, one side of the liquid separation seat is provided with the multicomponent liquid pipe, the fin group is arranged on the outer side of the liquid separation pipe, one end of the liquid separation pipe penetrates through the clamping seat to be connected with the water return pipe, the plug-in block connected with the fin group in a clamping mode is arranged above the plug-in block, the two sides of the heat conduction block are provided with the bolt connecting plate connected with the shell assembly bolt, and the slot seat is arranged above the heat conduction block.

As a further technical scheme, the lower part of the plug-in block is in a fin groove-shaped structure, the liquid distribution pipes are distributed in an array mode of the central axis of the liquid distribution seat, and the water return pipes and the diversion pipes are distributed in parallel.

As a further technical scheme, the casing subassembly includes backing plate, lower enclosure, control panel and top cap, the top of backing plate is provided with the lower enclosure of one end installation control panel, the top of lower enclosure is provided with the top cap of bolt assembly.

As a further technical scheme, the moisturizing component includes supporting seat, water pitcher, moisturizing mouth of a river, outlet valve and water pump, the water pitcher passes through supporting seat bolted connection the one end top of backing plate, the input of water pitcher is connected with the moisturizing mouth of a river, the output of water pitcher is connected with the water pump through the outlet valve.

As a further technical scheme, heating reflux mechanism includes assembly seat, heating cabin, temperature controller, interior socket, connecting rod, heating rod, water return valve and return water mouth, the heating cabin is in through assembly seat bolted connection the topside of backing plate, the input of heating cabin is connected with the input of play water pump, one side of heating cabin is provided with the temperature controller, the inside of heating cabin is provided with interior socket, just the both sides of interior socket are provided with the connecting rod, the interior avris of connecting rod is provided with multiunit parallel distribution's heating rod.

As a further technical scheme, a water return valve connected in a sleeved mode is arranged above the heating cabin, and a water return port is arranged at the top end of the water return valve.

As a further technical scheme, the split sleeve comprises a split pump, an inner valve body and an outer valve body, wherein the split pump is arranged at the output end of the heating cabin, the inner valve body is arranged at one end of the split pump, and the outer valve body is connected with the output end of the inner valve body.

The beneficial effects of the utility model are as follows:

the utility model mainly utilizes the flow diversion sleeve to open the liquid valve block, and then inputs the liquid valve block into the liquid diversion seat through the flow guide pipe arranged on the heat conduction assembly, under the interaction of the liquid diversion seat and the liquid diversion pipe, the heat generated by the water body is conducted into the plug-in block by adopting the fin group, and the heat of the water body is indirectly led into the mould through the heat conduction block and the slot seat, and the heat of the water body is not in contact heating between the water bodies, so that a great deal of loss of the water body is not caused, and the service life of the equipment is prolonged.

Drawings

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

FIG. 2 is a schematic side view of the present utility model;

FIG. 3 is a schematic cross-sectional perspective view of the present utility model;

FIG. 4 is a schematic cross-sectional perspective view of a heating reflow mechanism according to the present utility model;

fig. 5 is a schematic perspective view of a heat conducting component according to the present utility model.

Wherein: 1. a housing assembly; 101. a backing plate; 102. a lower enclosure; 103. a control panel; 104. a top cover; 2. a water replenishing member; 201. a support base; 202. a water tank; 203. a water supplementing port; 204. a water outlet valve; 205. a water outlet pump; 3. a heating reflux mechanism; 301. an assembly seat; 302. a heating chamber; 303. a temperature controller; 304. an inner socket; 305. a connecting rod; 306. a heating rod; 307. a water return valve; 308. a water return port; 4. a shunt kit; 401. a split flow pump; 402. an inner valve body; 403. an outer valve body; 5. a heat conducting component; 501. raising the rack; 502. a clamping seat; 503. a flow guiding pipe; 504. a liquid separating seat; 505. a liquid separating pipe; 506. a fin group; 507. a plug block; 508. a heat conduction block; 509. a bolt connecting plate; 5010. a socket seat; 5011. and a water return pipe.

Detailed Description

The present utility model will be further described in detail with reference to the following examples, which are only for the purpose of illustrating the utility model and are not to be construed as limiting the scope of the utility model.

According to fig. 1-5, this embodiment provides a high temperature molding temperature machine based on indirect heating of water, which comprises a housing assembly 1 and a heat conduction assembly 5, wherein a water supplementing member 2 assembled by a bolt is arranged at one end of the interior of the housing assembly 1, the output end of the water supplementing member 2 is connected with a heating reflux mechanism 3 connected with the housing assembly 1 by the bolt, the output end of the heating reflux mechanism 3 is connected with a split sleeve 4, and one side of the split sleeve 4 is provided with the heat conduction assembly 5 connected with the heating reflux mechanism 3 by the bolt;

the heat conduction assembly 5 comprises a lifting frame 501, a clamping seat 502, a flow guide pipe 503, a liquid separation seat 504, a liquid separation pipe 505, a fin group 506, an inserting block 507, a heat conduction block 508, a bolt connecting plate 509, a slot seat 5010 and a water return pipe 5011, wherein the clamping seat 502 is connected to the top side of the heating reflux mechanism 3 through a bolt of the lifting frame 501, one side of the clamping seat 502 is provided with the flow guide pipe 503 which is connected with the liquid separation seat 504 in a sleeved mode, the input end of the flow guide pipe 503 penetrates through the clamping seat 502, one side of the liquid separation seat 504 is provided with the multicomponent liquid pipe 505, the outer side of the liquid separation pipe 505 is provided with the fin group 506, one end of the liquid separation pipe 505 penetrates through the clamping seat 502 and is connected with the water return pipe 5011, the inserting block 507 is connected in a clamped mode, the upper side of the inserting block 507 is provided with the heat conduction block 508, two sides of the heat conduction block 508 are provided with the bolt connecting plate 509 connected with the shell assembly 1 through bolts, and the upper side of the heat conduction block 508 is provided with the slot seat 5010.

The lower part of the plug-in block 507 is in a fin groove-shaped structure, the liquid separating pipes 505 are distributed in an array with the central axis of the liquid separating seat 504, and the water return pipe 5011 and the flow guiding pipe 503 are distributed in parallel.

In this embodiment, the water is input to the liquid separating seat 504 at the inner side of the clamping seat 502 through the flow guiding pipe 503, the water is guided into the liquid separating pipe 505 through the liquid separating seat 504, and then the heat is conducted into the plug-in block 507 through the fin set 506, so that the heat is conducted into the slot seat 5010 above the heat conducting block 508 through the plug-in block 507 and the heat conducting block 508 for transmission, and after heat release is completed, the water is returned to the heating cabin 302 through the slot seat 5010 and the water return pipe 5011.

The shell assembly 1 comprises a base plate 101, a lower enclosure 102, a control panel 103 and a top cover 104, wherein the lower enclosure 102 with one end provided with the control panel 103 is arranged above the base plate 101, and the top cover 104 assembled by bolts is arranged above the lower enclosure 102.

In this embodiment, the device is placed at a processing site through the pad 101, so that the device is enclosed and carried by the upper side of the pad 101 through the lower enclosure 102 and the top cover 104, and when in use, the device is operated and debugged through the control panel 103 arranged at one end of the lower enclosure 102.

The water supplementing component 2 comprises a supporting seat 201, a water tank 202, a water supplementing port 203, a water outlet valve 204 and a water outlet pump 205, wherein the water tank 202 is connected above one end of the base plate 101 through bolts of the supporting seat 201, the water supplementing port 203 is connected to the input end of the water tank 202, and the water outlet pump 205 is connected to the output end of the water tank 202 through the water outlet valve 204.

In this embodiment, when in use, a sufficient amount of water is input into the water tank 202 through the water supplementing port 203, then the water outlet pump 205 is started to output power, and the water outlet valve 204 is opened, so that the water in the water tank 202 is output into the heating cabin 302 through the water outlet valve 204 and the water outlet pump 205.

The heating reflux mechanism 3 comprises an assembly seat 301, a heating cabin 302, a temperature controller 303, an inner insertion seat 304, a connecting rod 305, heating rods 306, a water return valve 307 and a water return port 308, wherein the heating cabin 302 is connected to the top side of the base plate 101 through the assembly seat 301 by bolts, the input end of the heating cabin 302 is connected with the input end of the water outlet pump 205, the temperature controller 303 is arranged on one side of the heating cabin 302, an inner socket 304 is arranged in the heating cabin 302, the connecting rods 305 are arranged on two sides of the inner socket 304, and a plurality of groups of heating rods 306 which are distributed in parallel are arranged on the inner side of the connecting rod 305.

In this embodiment, after a water body enters the heating cabin 302, the connecting rods 305 at two sides of the inner socket 304 are opened, so that multiple groups of heating rods 306 distributed in parallel are arranged at the inner side of the connecting rods 305 to generate heat, the water body in the heating cabin 302 is heated, and after heating is completed, the water body is tested by the sensor arranged in the temperature controller 303.

A water return valve 307 in sleeved connection is arranged above the heating cabin 302, and a water return port 308 is arranged at the top end of the water return valve 307.

In this embodiment, when contact between water bodies is required, the outer valve body 403 is opened to output water bodies, and after heat release, the water bodies are returned to the heating chamber 302 through the water return port 308 and the water return valve 307 to be heated again.

The split flow sleeve 4 comprises a split flow pump 401, an inner valve body 402 and an outer valve body 403, the split flow pump 401 is arranged at the output end of the heating cabin 302, the inner valve body 402 is arranged at one end of the split flow pump 401, and the output end of the inner valve body 402 is connected with the outer valve body 403.

In this embodiment, after the water body is tested, when the water body needs to be output, the inner valve body 402 and the split pump 401 are opened, so that the water body of the heating cabin 302 is output to the diversion pipe 503 through the cooperation of the inner valve body 402 and the split pump 401.

The working principle of the high-temperature die temperature machine based on water indirect heating is as follows: when the water heater is used, a sufficient amount of water is input into the water tank 202 through the water supplementing port 203, then the water outlet pump 205 is started to output power, the water in the water tank 202 is output into the heating cabin 302 through the water outlet valve 204 and the water outlet pump 205, after the water enters the heating cabin 302, the connecting rods 305 on two sides of the inner socket 304 are started, a plurality of groups of heating rods 306 which are arranged on the inner side of the connecting rods 305 and are distributed in parallel generate heat, the water in the heating cabin 302 is heated, after heating is finished, the water is tested through the sensors arranged by the temperature controller 303, when the water is tested, the inner valve body 402 and the shunt pump 401 are started, the water in the heating cabin 302 is output to the guide pipe 503 through the mutual matching of the inner valve body 402 and the shunt pump 401, the water is input into the liquid distributing seat 504 on the inner side of the clamping seat 502 through the guide pipe 503, the water is guided into the liquid distributing seat 505, the heat is conducted into the inserting blocks 507 through the fin groups 506, the heat is conducted into the inserting grooves 507 above the heat blocks 508 through the inserting blocks 507, after the water is heated, the water is required to be output through the water returning seat 5010, the water is heated through the water returning seat 403, and the water returning valve body is heated after the water is heated, and the water is heated through the water returning valve body is heated, and the water is heated, after the water is heated, and after the water is heated, and the water is returned is heated, and after the water is heated, and after the water is heated.

The foregoing has shown and described the basic principles, principal features and advantages of the utility model. It will be understood by those skilled in the art that the present utility model is not limited to the embodiments described above, and that the above embodiments and descriptions are merely illustrative of the principles of the present utility model, and various changes and modifications may be made without departing from the spirit and scope of the utility model, which is defined in the appended claims. The scope of the utility model is defined by the appended claims and equivalents thereof.

Claims (7)

1. The utility model provides a high temperature die temperature machine based on water indirect heating, includes casing subassembly (1) and heat conduction subassembly (5), its characterized in that: the water supplementing device is characterized in that a water supplementing component (2) assembled by a bolt is arranged at one end of the inside of the shell assembly (1), the output end of the water supplementing component (2) is connected with a heating reflux mechanism (3) connected with the shell assembly (1) by the bolt, the output end of the heating reflux mechanism (3) is connected with a shunt sleeve (4), and one side of the shunt sleeve (4) is provided with a heat conducting component (5) connected with the heating reflux mechanism (3) by the bolt;

the heat conduction assembly (5) comprises a lifting frame (501), a clamping seat (502), a flow guide pipe (503), a liquid separation seat (504), a liquid separation pipe (505), a fin group (506), a plug-in block (507), a heat conduction block (508), a bolt connection plate (509), a slot seat (5010) and a water return pipe (5011), wherein the clamping seat (502) is connected with the top side of the heating reflux mechanism (3) through the lifting frame (501) in a bolt manner, one side of the clamping seat (502) is provided with the flow guide pipe (503) which is connected with the flow separation sleeve (4) in a sleeved manner, the input end of the flow guide pipe (503) penetrates through the clamping seat (502) and is connected with the liquid separation seat (504), one side of the liquid separation seat (504) is provided with the multi-component liquid pipe (505), one end of the liquid separation pipe (505) penetrates through the clamping seat (502) and is connected with the water return pipe (5011), the upper side of the fin group (506) is provided with the block (507) which is connected with the bolt connection plate (509) and the two sides of the heat conduction block (508) are connected with the bolt connection plate (509), and a slot seat (5010) is arranged above the heat conduction block (508).

2. A high temperature die temperature machine based on indirect heating of water according to claim 1, characterized in that: the lower part of the plug-in block (507) is in a fin groove-shaped structure, the liquid separating pipes (505) are distributed in a central axis array of the liquid separating seat (504), and the water return pipes (5011) and the guide pipes (503) are distributed in parallel.

3. A high temperature die temperature machine based on indirect heating of water according to claim 1, characterized in that: the shell assembly (1) comprises a base plate (101), a lower enclosure (102), a control panel (103) and a top cover (104), wherein the lower enclosure (102) with one end provided with the control panel (103) is arranged above the base plate (101), and the top cover (104) assembled by bolts is arranged above the lower enclosure (102).

4. A high temperature die temperature machine based on indirect heating of water according to claim 3, characterized in that: the water supplementing component (2) comprises a supporting seat (201), a water tank (202), a water supplementing port (203), a water outlet valve (204) and a water outlet pump (205), wherein the water tank (202) is connected above one end of the base plate (101) through the supporting seat (201) through bolts, the water supplementing port (203) is connected with the input end of the water tank (202), and the output end of the water tank (202) is connected with the water outlet pump (205) through the water outlet valve (204).

5. A high temperature die temperature machine based on indirect heating of water according to claim 3 or 4, characterized in that: heating reflux mechanism (3) are including assembly seat (301), heating cabin (302), temperature controller (303), interior seat (304), connecting rod (305), heating rod (306), water return valve (307) and return water mouth (308), heating cabin (302) are in through assembly seat (301) bolted connection the top side of backing plate (101), the input of heating cabin (302) is connected with the input of play water pump (205), one side of heating cabin (302) is provided with temperature controller (303), the inside of heating cabin (302) is provided with interior socket (304), just the both sides of interior seat (304) are provided with connecting rod (305), the interior limit side of connecting rod (305) is provided with multiunit parallel distribution's heating rod (306).

6. The high temperature die temperature machine based on indirect heating of water according to claim 5, wherein: a water return valve (307) connected in a sleeved mode is arranged above the heating cabin (302), and a water return port (308) is arranged at the top end of the water return valve (307).

7. The high temperature die temperature machine based on indirect heating of water according to claim 5, wherein: the split flow sleeve (4) comprises a split flow pump (401), an inner valve body (402) and an outer valve body (403), the split flow pump (401) is arranged at the output end of the heating cabin (302), the inner valve body (402) is arranged at one end of the split flow pump (401), and the outer valve body (403) is connected with the output end of the inner valve body (402).

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