CN218270309U - Energy storage type high-energy-efficiency heat exchange device - Google Patents

Abstract

The utility model relates to a heat transfer technology field especially relates to a heat transfer device is imitated to energy storage type height, including outside tubular metal resonator, refrigerant import copper pipe is installed to the side tip of outside tubular metal resonator, fixed mounting has third welding seal baffle between the circumference surface of refrigerant import copper pipe and the outside tubular metal resonator inner wall, is located refrigerant import copper pipe top the internally mounted of outside tubular metal resonator has the red copper screwed pipe of second, the circumference surface cover of the red copper screwed pipe of second is equipped with first red copper screwed pipe, the side tip of refrigerant import copper pipe runs through inside first red copper screwed pipe, the upper end of outside tubular metal resonator rear side runs through fixed mounting and has the heat exchange circulating water outlet pipe. The utility model discloses an open refrigerant outlet joint, refrigerant outlet joint opens the back, and the refrigerant enters into refrigerant export copper pipe through first red copper screwed pipe, outwards discharges through refrigerant export copper pipe at last, and overall arrangement reasonable in design effectively improves the refrigerant availability factor.

Description

Energy storage type high-energy-efficiency heat exchange device

Technical Field

The utility model relates to a heat transfer technical field especially relates to a heat transfer device is imitated to energy storage type high energy.

Background

Heat exchange is the process of heat transfer between two objects or parts of the same object due to temperature differences. The heat exchange is generally accomplished through heat conduction, thermal convection and thermal radiation three kinds of modes, and general heat exchange circulating water is accomplished in indirect heating equipment, but current indirect heating equipment is when carrying out the heat transfer to the heat exchange circulating water, because the refrigerant pipeline sets up comparatively single unreasonable, leads to heat exchange circulating water exchange efficiency to be lower.

SUMMERY OF THE UTILITY MODEL

In order to overcome the defects of the prior art, the utility model provides an energy storage type high-energy-efficiency heat exchange device.

In order to solve the technical problem, the utility model provides a following technical scheme: the utility model provides an energy storage type high energy efficiency heat exchange device, includes outside metal tube, refrigerant import copper pipe is installed to the side tip of outside metal tube, fixed mounting has third welding seal baffle between the circumferential surface of refrigerant import copper pipe and the outside metal tube inner wall, is located refrigerant import copper pipe top the internally mounted of outside metal tube has the red copper screwed pipe of second, the circumferential surface cover of the red copper screwed pipe of second is equipped with first red copper screwed pipe, the side tip of refrigerant import copper pipe runs through inside first red copper screwed pipe, the upper end of outside metal tube rear side runs through fixed mounting has the heat exchange circulating water outlet pipe, keeps away from refrigerant import copper pipe one side the side tip of outside metal tube is installed refrigerant export copper pipe, the tip of refrigerant export copper pipe runs through to install in first red copper screwed pipe.

As a preferred technical scheme of the utility model, equal fixed mounting has first welding seal baffle between two liang of first red copper screwed pipe, the red copper screwed pipe of second and refrigerant import copper pipe, the heat exchange circulating water import has all been seted up at both ends around the red copper screwed pipe of second.

As an optimal technical scheme of the utility model, be located outside metal tube rear side outside metal tube, the red copper screwed pipe of second and refrigerant export copper pipe equal fixed mounting between two liang have a second welding seal baffle, lie in outside metal tube the circumference surface cover of refrigerant export copper pipe is equipped with refrigerant outlet joint, lies in outside metal tube the circumference surface cover of refrigerant import copper pipe is equipped with refrigerant inlet joint.

Compared with the prior art, the utility model discloses the beneficial effect that can reach is:

1. heat exchange circulating water is lived the refrigerant parcel completely, install between outside tubular metal resonator and the red copper screwed pipe of second through the first red copper screwed pipe that will be equipped with the refrigerant, thereby can make the water that needs heat exchange cycle fully contact the refrigerant, make the heat exchange more abundant, all fix through third welding seal baffle or second welding seal baffle between every pipeline simultaneously, thereby effectively keep the leakproofness between every pipeline, when needs discharge heat cycle's water, hot circulating water can outwards discharge through heat exchange circulating water outlet pipe.

2. Through opening refrigerant exit joint, refrigerant exit joint opens the back, and the refrigerant enters into refrigerant export copper pipe through first red copper screwed pipe, outwards discharges through refrigerant export copper pipe at last, and overall arrangement reasonable in design effectively improves refrigerant availability factor.

Drawings

Fig. 1 is a schematic structural view of a refrigerant inlet joint of the present invention;

fig. 2 is an enlarged schematic view of a portion a of fig. 1 according to the present invention;

fig. 3 is a schematic structural view of the external metal tube of the present invention.

Wherein: 1. a refrigerant inlet joint; 11. a first welded sealing baffle; 12. a second welded sealing baffle; 13. a refrigerant outlet copper pipe; 2. a refrigerant inlet copper pipe; 3. an outer metal tube; 4. a first copper threaded pipe; 5. a second red copper threaded pipe; 6. a heat exchange circulating water outlet pipe; 7. thirdly, welding the sealing baffle; 8. a heat exchange circulating water inlet; 9. refrigerant outlet joint.

Detailed Description

In order to make the technical means, creation features, achievement objects and functions of the present invention easy to understand, the present invention will be further explained with reference to the following embodiments, however, the following embodiments are only preferred embodiments of the present invention, and not all embodiments are included. Based on the embodiments in the implementation, other embodiments obtained by those skilled in the art without any creative work belong to the protection scope of the present invention. The experimental procedures in the following examples were carried out in a conventional manner unless otherwise specified, and materials, reagents and the like used in the following examples were commercially available unless otherwise specified.

Example 1: as shown in fig. 1 and fig. 2 and fig. 3, the energy storage type high-energy-efficiency heat exchange device comprises an external metal pipe 3, a refrigerant inlet copper pipe 2 is installed at the side end of the external metal pipe 3, a third welding sealing baffle 7 is fixedly installed between the circumferential surface of the refrigerant inlet copper pipe 2 and the inner wall of the external metal pipe 3, a second red copper threaded pipe 5 is installed inside the external metal pipe 3 above the refrigerant inlet copper pipe 2, a first red copper threaded pipe 4 is sleeved on the circumferential surface of the second red copper threaded pipe 5, the first red copper threaded pipe 4 is sleeved outside the second red copper threaded pipe 5, so that the second red copper threaded pipe 5 is wrapped by a refrigerant, the refrigerant is located between the external metal pipe 3 and the second red copper threaded pipe 5, circulating water needing heat exchange is filled into the external metal pipe 3 through a heat exchange circulating water inlet 8, the circulating water needing heat exchange enters the external metal pipe 3 and the second red copper threaded pipe 5 respectively, the heat exchange circulating water completely wraps the circulating water, the circulating water is installed at the side end of the external metal pipe 3 and the side of the second red copper threaded pipe 4, and the side end of the refrigerant outlet copper pipe 13 of the external metal pipe 3 is far away from the refrigerant outlet copper pipe, and the side of the refrigerant outlet copper pipe 13, and the refrigerant outlet copper pipe 13 of the internal circulating water of the refrigerant is installed on the side of the external metal pipe 3, and the side of the refrigerant inlet copper pipe.

First red copper screwed pipe 4, equal fixed mounting has first welding seal baffle 11 between two liang of second red copper screwed pipe 5 and refrigerant import copper pipe 2, heat exchange circulating water import 8 has all been seted up at the front and back both ends of second red copper screwed pipe 5, the outside metal tube 3 that is located outside metal tube 3 rear side, equal fixed mounting has second welding seal baffle 12 between two liang of second red copper screwed pipe 5 and refrigerant export copper pipe 13, the circumference surface cover of refrigerant export copper pipe 13 that is located outside metal tube 3 is equipped with refrigerant outlet joint 9, the user can be through opening refrigerant outlet joint 9, refrigerant outlet joint 9 opens the back, the refrigerant passes through first red copper screwed pipe 4 and enters into refrigerant export copper pipe 13, outwards discharge through refrigerant export copper pipe 13 at last, overall arrangement reasonable in design, effectively improve refrigerant availability factor, the circumference surface cover of refrigerant import copper pipe 2 that is located outside metal tube 3 is equipped with refrigerant inlet joint 1.

The working principle is as follows:

the refrigerant inlet copper pipe 2 is connected with an external refrigerant pipeline through a refrigerant inlet joint 1, the external refrigerant pipeline injects the refrigerant into the refrigerant inlet copper pipe 2, the refrigerant enters the inside of a first red copper threaded pipe 4 through the refrigerant inlet copper pipe 2, the first red copper threaded pipe 4 is sleeved outside a second red copper threaded pipe 5, so the refrigerant can wrap the second red copper threaded pipe 5, the refrigerant is positioned between an external metal pipe 3 and the second red copper threaded pipe 5, circulating water needing heat exchange is injected into the external metal pipe 3 through a heat exchange circulating water inlet 8, the circulating water needing heat exchange respectively enters the external metal pipe 3 and the second red copper threaded pipe 5, the heat exchange circulating water completely wraps the refrigerant at the moment, the first red copper threaded pipe 4 filled with the refrigerant is installed between the external metal pipe 3 and the second red copper threaded pipe 5, so that water needing heat exchange circulation is fully contacted, the heat exchange is more sufficient, meanwhile, the heat exchange is completely fixed through a third welding sealing baffle 7 or a second welding sealing baffle 12 between every two pipelines, the sealing performance between every pipelines is effectively kept, the circulating water needing heat exchange can be discharged to the circulating water when the circulating water is discharged out, and the circulating water is discharged to the outside through a heat exchange outlet pipe 6.

When the refrigerant needs to be replaced, the user can open the refrigerant outlet joint 9, and after the refrigerant outlet joint 9 was opened, the refrigerant entered into the refrigerant outlet copper pipe 13 through the first red copper screwed pipe 4, and finally outwards discharged through the refrigerant outlet copper pipe 13, and overall layout reasonable in design effectively improves the refrigerant availability factor.

The embodiments of the present invention have been described in detail with reference to the drawings, but the present invention is not limited thereto, and various changes can be made without departing from the gist of the present invention within the knowledge of those skilled in the art.

Claims (6)

1. The utility model provides a high-energy-efficiency heat exchange device of energy storage type, includes outside tubular metal resonator (3), its characterized in that, refrigerant import copper pipe (2) is installed to the side tip of outside tubular metal resonator (3), fixed mounting has third welding seal baffle (7) between the circumferential surface of refrigerant import copper pipe (2) and outside tubular metal resonator (3) inner wall, is located refrigerant import copper pipe (2) top the internally mounted of outside tubular metal resonator (3) has second red copper screwed pipe (5), the circumferential surface cover of second red copper screwed pipe (5) is equipped with first red copper screwed pipe (4), the side tip of refrigerant import copper pipe (2) runs through inside first red copper screwed pipe (4), the upper end of outside tubular metal resonator (3) rear side runs through fixed mounting has heat exchange circulation water outlet pipe (6), keeps away from refrigerant import copper pipe (2) one side the side tip of outside tubular metal resonator (3) is installed and is exported copper pipe (13), the tip of export copper pipe (13) runs through and installs in first red copper screwed pipe (4).

2. The energy storage type high-energy-efficiency heat exchange device according to claim 1, wherein a first welding sealing baffle plate (11) is fixedly arranged between each two of the first red copper threaded pipe (4), the second red copper threaded pipe (5) and the refrigerant inlet copper pipe (2).

3. The energy storage type high-energy-efficiency heat exchange device according to claim 1, wherein the front end and the rear end of the second red copper threaded pipe (5) are both provided with a heat exchange circulating water inlet (8).

4. The energy storage type high-energy-efficiency heat exchange device according to claim 1, wherein a second welding sealing baffle plate (12) is fixedly arranged between the external metal pipe (3) positioned at the rear side of the external metal pipe (3), the second red copper threaded pipe (5) and the refrigerant outlet copper pipe (13) in pairs.

5. The energy-storage type high-energy-efficiency heat exchange device according to claim 1, wherein the refrigerant outlet joint (9) is sleeved on the circumferential surface of the refrigerant outlet copper pipe (13) positioned outside the external metal pipe (3).

6. The energy-storage type high-energy-efficiency heat exchange device according to claim 1, wherein the refrigerant inlet joint (1) is sleeved on the circumferential surface of the refrigerant inlet copper pipe (2) positioned outside the external metal pipe (3).

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