CN222920953U - Cooling energy-saving device for compression molding process - Google Patents

Abstract

The utility model relates to the technical field of cooling energy saving, specifically a cooling energy saving device of a compression molding process, comprising a frame, two baffle tubes are fixedly installed inside the frame, a heat dissipation component is movably arranged inside the baffle tube, the heat dissipation component comprises a rotating shaft rotatably connected to the inside of the baffle tube, a spiral blade is fixedly installed on the outer surface of the rotating shaft, a fan blade is fixedly installed on the surface of one end of the rotating shaft, a heat conduction component is fixedly arranged at one end of the baffle tube, and the heat conduction component comprises two three-way pipes, and two serpentine heat conduction pipes are fixedly connected between the two three-way pipes. In the utility model, the fan blades are rotated by the power of the flow of the coolant, the coolant is initially dissipated, and part of the heat carried by the coolant is discharged into the air, thereby reducing the heat introduced by the coolant into the evaporator of the chiller, reducing the temperature difference during heat exchange, reducing the power of the chiller, and reducing the energy consumed by the chiller when it is working.

Description

Cooling energy-saving device for compression molding process

Technical Field

The utility model relates to the technical field of cooling energy conservation, in particular to a cooling energy-saving device for a compression molding process.

Background

Compression molding, also known as compression molding or compression molding, is a method of molding a thermosetting plastic in which a pre-mixed or pre-prepared plastic raw material is placed in a mold, and then flows and fills a cavity of the mold by the combined action of heat and pressure, thereby solidifying to form a desired plastic product, and the solidified plastic product needs to be cooled to ensure the stability of its shape and size;

The cooling is mostly formed by three circulation, and the first circulation is the cooling liquid circulation in the cooling tube of mould, and the cooling liquid in the cooling tube carries out the heat exchange with the evaporimeter of cooling water machine when circulating, cools down the cooling liquid, and the direct import of absorbing heat cooling liquid department carries out the heat exchange, and the heat that the cooling liquid carried is more, and too much heat exchange can make the power of cooling water machine rise, consumes more energy, is inconvenient for carrying out preliminary heat dissipation itself through the power that the cooling liquid flows.

Disclosure of utility model

The utility model aims to provide a cooling energy-saving device for a compression molding process, which aims to solve the problems in the background technology.

In order to achieve the above purpose, the present utility model provides the following technical solutions:

the utility model provides a cooling economizer of compression molding technology, includes the frame, the inside fixed mounting of frame has two baffling pipes, the inside activity of baffling pipe is equipped with the radiator unit, the radiator unit is including rotating the pivot of connecting in the baffling pipe inside, pivot outside surface fixed mounting has helical blade, pivot one end fixed surface installs the flabellum, baffling pipe one end is fixed and is equipped with heat conduction subassembly, heat conduction subassembly includes two three-way pipes, two fixed intercommunication has two snakelike heat conduction pipes between the three-way pipe.

The baffle tube is characterized in that a fixed seat is fixedly arranged on the inner surface of the baffle tube, and the rotating shaft is rotationally connected with the fixed seat.

The baffle tube is characterized in that the outer side surface of the baffle tube is fixedly embedded and provided with an extension tube, the rotating shaft penetrates through the extension tube, and a sealing piece is arranged between the extension tube and the rotating shaft.

The water inlet pipe is fixedly arranged on the surface of one end of the baffle pipe, the water outlet pipe is fixedly arranged on the surface of the other end of the baffle pipe, one end of the three-way pipe is fixedly communicated with the connecting pipe, and one end of the connecting pipe is fixedly connected with one water inlet pipe.

Preferably, one ends of the two three-way pipes are fixedly communicated with the two drain pipes respectively.

The heat-conducting plate structure is characterized in that the outer side surface of the serpentine heat-conducting pipe is movably attached with a plurality of first heat-conducting plates, a plurality of second heat-conducting plates are movably attached to the symmetrical positions of the outer side surface of the serpentine heat-conducting pipe and the first heat-conducting plates, and connecting rods are fixedly connected to the two ends of the first heat-conducting plates and the two ends of the second heat-conducting plates.

Preferably, the two ends of the connecting rod respectively penetrate through the first heat conducting plate and the second heat conducting plate which are connected with the connecting rod, limiting sheets are fixedly arranged at the two ends of the connecting rod, clamping plates are rotatably connected at the two ends of the outer side surface of the connecting rod at the first heat conducting plate, clamping grooves are formed in one end of each clamping plate, and the clamping grooves are movably clamped with the connecting rod at the second heat conducting plate.

Compared with the prior art, the utility model has the beneficial effects that:

1. The cooling liquid drives the spiral blades to rotate through the baffle pipes, so that the spiral blades rotate, the fan blades are driven to rotate, the outside air is driven to blow to the heat conduction assembly, heat of the cooling liquid conducted to the heat conduction assembly is discharged to the air, the fan blades rotate through the flowing power of the cooling liquid, the cooling liquid is subjected to preliminary heat dissipation, part of heat carried by the cooling liquid is discharged into the air, the heat of the cooling liquid at the evaporator of the water chiller is reduced, the temperature difference in heat exchange is reduced, the power of the water chiller is reduced, and the energy consumed in the working process of the water chiller is reduced.

2. When the cooling liquid passes through the snakelike heat conduction pipe, heat is conducted to the first heat conduction plate and the second heat conduction plate, the area when the air flows and dissipates heat is increased, so that the heat dissipation rate of the cooling liquid is accelerated, the clamping groove is separated from the connecting rod through the rotating clamping plate, the first heat conduction plate and the second heat conduction plate are detached from the surface of the snakelike heat conduction pipe, the first heat conduction plate and the second heat conduction plate are convenient to detach and clean, and the heat conduction effect of the first heat conduction plate and the second heat conduction plate is kept.

Drawings

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

FIG. 2 is a schematic view of a vertical cross-section of a baffle tube according to the present utility model;

FIG. 3 is a schematic view of the overall structure of the heat conduction assembly of the present utility model;

FIG. 4 is a schematic side sectional view of a heat conducting component according to the present utility model;

fig. 5 is a schematic diagram of a split structure of a heat conducting component in the present utility model.

The heat-conducting device comprises a frame 1, a baffle pipe 101, a water inlet pipe 102, a water outlet pipe 103, a connecting pipe 104, a heat-radiating component 2, a heat-conducting plate 201, an extension pipe 202, a rotating shaft 203, a spiral blade 204, a fixing seat 205, a fan blade 206, a sealing element 3, a heat-conducting component 301, a three-way pipe 302, a snake-shaped heat-conducting pipe 303, a first heat-conducting plate 304, a second heat-conducting plate 305, a connecting rod 306, a clamping plate 307, a limiting piece 308 and a clamping groove.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Referring to fig. 1 to 5, in an embodiment of the present utility model, a cooling energy-saving device for a compression molding process includes a frame 1, two baffle pipes 101 are fixedly installed inside the frame 1, a heat dissipation assembly 2 is movably disposed inside the baffle pipes 101, the heat dissipation assembly 2 includes a rotating shaft 202 rotatably connected inside the baffle pipes 101, a spiral blade 203 is fixedly installed on an outer surface of the rotating shaft 202, a fan blade 205 is fixedly installed on one end surface of the rotating shaft 202, a heat conduction assembly 3 is fixedly disposed at one end of the baffle pipes 101, the heat conduction assembly 3 includes two tee pipes 301, and two serpentine heat conduction pipes 302 are fixedly connected between the two tee pipes 301.

Specifically, the cooling liquid passes through the inside of the deflector 101 to drive the fan blades 205 to rotate, so that the external air is blown to the heat conduction assembly 3, and the heat conduction assembly 3 dissipates heat.

In the embodiment, as shown in fig. 1, a water inlet pipe 102 is fixedly installed on one end surface of a baffle pipe 101, a water outlet pipe 103 is fixedly installed on the other end surface of the baffle pipe 101, a connecting pipe 104 is fixedly communicated with one end of a three-way pipe 301, one end of the connecting pipe 104 is fixedly connected with one water inlet pipe 102, and one ends of two three-way pipes 301 are respectively fixedly communicated with two water outlet pipes 103.

In this embodiment, by communicating the inlet pipe 102 and one tee 301 with the heat conducting pipes of the mold, the cooling liquid is circulated through the inside of the two baffle pipes 101.

In the embodiment, as shown in fig. 2, a fixing seat 204 is fixedly arranged on the inner surface of the baffle tube 101, a rotating shaft 202 is rotatably connected with the fixing seat 204, an extension tube 201 is fixedly embedded and arranged on the outer surface of the baffle tube 101, the rotating shaft 202 penetrates through the extension tube 201, and a sealing element 206 is arranged between the extension tube 201 and the rotating shaft 202.

When the cooling liquid passes through the inside of the deflector 101, the cooling liquid pushes the spiral blade 203 to rotate, so that the spiral blade 203 drives the rotating shaft 202 to rotate, the fan blade 205 rotates, the outside air is guided to blow to the heat conduction assembly 3, the heat of the cooling liquid conducted to the heat conduction assembly 3 is discharged into the air, the fan blade 205 is enabled to rotate through the flowing power of the cooling liquid, the cooling liquid is primarily radiated, part of the heat carried by the cooling liquid is discharged into the air, the heat of the cooling liquid at the evaporator of the water chiller is reduced, the temperature difference during heat exchange is reduced, the power of the water chiller is reduced, and the energy consumed during the work of the water chiller is reduced.

As shown in fig. 3-5, in this embodiment, a plurality of first heat conducting plates 303 are movably attached to the outer side surface of the serpentine heat conducting tube 302, a plurality of second heat conducting plates 304 are movably attached to the symmetrical positions of the outer side surface of the serpentine heat conducting tube 302 and the first heat conducting plates 303, connecting rods 305 are fixedly connected to the two ends of the first heat conducting plates 303 and the second heat conducting plates 304, the two ends of the connecting rods 305 respectively penetrate through the first heat conducting plates 303 and the second heat conducting plates 304 connected with the connecting rods, limiting plates 307 are fixedly mounted at the two ends of the connecting rods 305, clamping plates 306 are rotatably connected to the two ends of the outer side surface of the connecting rods 305 at the first heat conducting plates 303, clamping grooves 308 are formed in one ends of the clamping plates 306, and the clamping grooves 308 are movably clamped with the connecting rods 305 at the second heat conducting plates 304.

In specific implementation, when the cooling liquid passes through the serpentine heat-conducting pipe 302, heat is conducted to the first heat-conducting plate 303 and the second heat-conducting plate 304, the area of the cooling liquid during air flow heat dissipation is increased, so that the heat dissipation rate of the cooling liquid is accelerated, the clamping groove 308 is separated from the connecting rod 305 by rotating the clamping plate 306, the first heat-conducting plate 303 and the second heat-conducting plate 304 are detached from the surface of the serpentine heat-conducting pipe 302, the first heat-conducting plate 303 and the second heat-conducting plate 304 are convenient to detach and clean, and the heat-conducting effect of the first heat-conducting plate 303 and the second heat-conducting plate 304 is kept.

It will be evident to those skilled in the art that the utility model is not limited to the details of the foregoing illustrative embodiments, and that the present utility model may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are, therefore, to be considered in all respects as illustrative and not restrictive, the scope of the utility model being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Furthermore, it should be understood that although the present disclosure describes embodiments, not every embodiment is provided with a separate embodiment, and that this description is provided for clarity only, and that the disclosure is not limited to the embodiments described in detail below, and that the embodiments described in the examples may be combined as appropriate to form other embodiments that will be apparent to those skilled in the art.

Claims (7)

1. The utility model provides a cooling economizer of compression molding technology, its characterized in that, includes frame (1), the inside fixed mounting of frame (1) has two baffling pipes (101), baffling pipe (101) internal activity is equipped with radiator unit (2), radiator unit (2) are including rotating to connect in inside pivot (202) of baffling pipe (101), pivot (202) outside surface fixed mounting has helical blade (203), pivot (202) one end surface fixed mounting has flabellum (205), baffling pipe (101) one end is fixed to be equipped with heat conduction subassembly (3), heat conduction subassembly (3) are including two three-way pipe (301), two fixed intercommunication has two snakelike heat pipes (302) between three-way pipe (301).

2. The cooling energy-saving device for a compression molding process according to claim 1, wherein a fixing seat (204) is fixedly arranged on the inner surface of the baffle tube (101), and the rotating shaft (202) is rotatably connected with the fixing seat (204).

3. The cooling energy-saving device for compression molding process according to claim 1, wherein the baffle tube (101) is fixedly embedded in the outer surface of the baffle tube, an extension tube (201) is installed, the rotating shaft (202) penetrates through the extension tube (201), and a sealing element (206) is arranged between the extension tube (201) and the rotating shaft (202).

4. The cooling energy-saving device for a compression molding process according to claim 1, wherein a water inlet pipe (102) is fixedly arranged on one end surface of the baffle pipe (101), a water outlet pipe (103) is fixedly arranged on the other end surface of the baffle pipe (101), a connecting pipe (104) is fixedly communicated with one end of one three-way pipe (301), and one end of the connecting pipe (104) is fixedly connected with one water inlet pipe (102).

5. A cooling and energy saving device for a compression moulding process according to claim 4, wherein one end of two said three-way pipes (301) is fixedly connected to two drain pipes (103), respectively.

6. The cooling and energy-saving device for the compression molding process according to claim 1, wherein a plurality of first heat conducting plates (303) are movably attached to the outer side surface of the serpentine heat conducting pipe (302), a plurality of second heat conducting plates (304) are movably attached to the symmetrical positions of the outer side surface of the serpentine heat conducting pipe (302) and the first heat conducting plates (303), and connecting rods (305) are fixedly connected to two ends of the first heat conducting plates (303) and the second heat conducting plates (304).

7. The cooling and energy-saving device for the compression molding process according to claim 6, wherein two ends of the connecting rod (305) respectively penetrate through a first heat conducting plate (303) and a second heat conducting plate (304) which are connected with the connecting rod, limiting pieces (307) are fixedly installed at two ends of the connecting rod (305), clamping plates (306) are rotatably connected at two ends of the outer side surface of the connecting rod (305) at the first heat conducting plate (303), clamping grooves (308) are formed in one end of each clamping plate (306), and the clamping grooves (308) are movably clamped with the connecting rod (305) at the second heat conducting plate (304).