CN214120470U

CN214120470U - High-efficiency cold accumulator

Info

Publication number: CN214120470U
Application number: CN202023259799.6U
Authority: CN
Inventors: 杨鲁旭
Original assignee: Jiangsu Greenland Heat Transfer Technology Co ltd
Current assignee: Jiangsu Greenland Heat Transfer Technology Co ltd
Priority date: 2020-12-29
Filing date: 2020-12-29
Publication date: 2021-09-03
Anticipated expiration: 2030-12-29

Abstract

The utility model discloses a high-efficient regenerator belongs to regenerator technical field, including pond, medium feed arrangement, medium discharging device, first coil pipe and second coil pipe, pond horizontal installation is subaerial, first coil pipe and second coil pipe are linked together with medium feed arrangement and medium discharging device respectively, first coil pipe is located the pond, the second coil pipe also is located the pond, crisscross setting of first coil pipe and second coil pipe, the both ends of first coil pipe are linked together with medium feed arrangement and medium discharging device respectively, the both ends of second coil pipe are linked together with medium feed arrangement and medium discharging device respectively. The utility model discloses a crisscross setting of first coil pipe and second coil pipe can improve the cooling efficiency to the water in the pond, and the effect to the cooling of rivers is better.

Description

High-efficiency cold accumulator

Technical Field

The utility model relates to a technical field of regenerator especially relates to a high-efficient regenerator.

Background

The power consumption in the industrial process is enormous, and as society develops, the problem of power shortage becomes a new development problem, and thus effective allocation of power is performed in various ways. There is a regenerator among the prior art, this kind of regenerator cools down for the millet electricity period at night electricity charging to the cell body, then obtains the electric energy after the water heaies up in the daytime, and the regenerator that adopts this kind of mode sets up the pipeline because of the coil pipe longer, consequently can't accomplish the purpose of high-efficient cooling, consequently needs to find the mode of a high-efficient cooling to solve this problem urgently.

SUMMERY OF THE UTILITY MODEL

An embodiment of the utility model provides a high-efficient regenerator to solve the technical problem who can't cool down the effect fast to the medium.

The embodiment of the utility model provides an adopt following technical scheme: the utility model provides a high-efficient regenerator, includes pond, medium feed arrangement, medium discharging device, first coil pipe and second coil pipe, pond horizontal installation is subaerial, first coil pipe and second coil pipe are linked together with medium feed arrangement and medium discharging device respectively, first coil pipe is located the pond, the second coil pipe also is located the pond, first coil pipe and second coil pipe crisscross setting, the both ends of first coil pipe are linked together with medium feed arrangement and medium discharging device respectively, the both ends of second coil pipe are linked together with medium feed arrangement and medium discharging device respectively.

Further, medium feed arrangement includes first feeding branch pipe, second feeding branch pipe and feed inlet, the feed inlet is located the pond, first feeding branch pipe is linked together with the feed inlet, second feeding branch pipe is located first feeding branch pipe and second feeding branch pipe is linked together with first feeding branch pipe, first feeding branch pipe be linked together with the one end of second coil pipe, second feeding branch pipe is linked together with the one end of first coil pipe.

Further, medium discharging device includes first ejection of compact branch pipe, second ejection of compact branch pipe and discharge gate, the discharge gate is located the pond and is located the side of feed inlet, first ejection of compact branch pipe is linked together with the discharge gate, second ejection of compact branch pipe is located first ejection of compact branch pipe, second ejection of compact branch pipe is linked together with first ejection of compact branch pipe, the other end with first coil pipe of first ejection of compact branch pipe is linked together, the other end with the second coil pipe of second ejection of compact branch pipe is linked together.

Further, be equipped with the coil pipe support frame on the lateral wall in pond, the vertical setting of coil pipe support frame, first coil pipe and second coil pipe fixed connection are on the coil pipe support frame.

Furthermore, the first coil pipe and the second coil pipe are both made of corrosion-resistant metal materials.

The embodiment of the utility model provides an above-mentioned at least one technical scheme who adopts can reach following beneficial effect:

one of them, the first coil pipe and the second coil pipe are arranged in a staggered mode, so that the cooling efficiency of water in the water pool can be improved, and the effect of cooling water is better.

Secondly, the medium enters from the feed inlet and is conveyed into the second coil pipe through the first feed branch pipe respectively, the medium is conveyed into the second feed branch pipe through the first feed branch pipe so as to move the medium into the first coil pipe, the medium is moved into the medium discharging device by the first coil pipe and the second coil pipe, the medium is moved forward by the first coil pipe and the second coil pipe so as to uniformly cool the water in the water tank, after the water is cooled, when the medium is discharged, the medium in the ground of the first coil pipe enters the discharge port through the first discharge branch pipe, the medium in the second coil pipe enters the first discharge branch pipe through the second discharge branch pipe so as to convey the medium into the discharge port, the medium in the first discharge branch pipe and the second discharge branch pipe is discharged outwards through the discharge port, and after the water is cooled at night, the water in the water tank can be heated due to the natural temperature rise in the daytime, the heat generated in the temperature rising process can be utilized to generate electricity.

Drawings

The accompanying drawings, which are described herein, serve to provide a further understanding of the invention and constitute a part of this specification, and the exemplary embodiments and descriptions thereof are provided for explaining the invention without unduly limiting it. In the drawings:

fig. 1 is a first schematic diagram of the present invention;

FIG. 2 is a second schematic view of the present invention;

reference numerals

Pond 1, coil pipe support frame 2, medium feed arrangement 3, first feeding branch pipe 31, second feeding branch pipe 32, feed inlet 33, medium discharging device 4, first ejection of compact branch pipe 41, second ejection of compact branch pipe 42, discharge gate 43, first coil pipe 5, second coil pipe 6.

Detailed Description

To make the purpose, technical solution and advantages of the present invention clearer, the following will combine the embodiments of the present invention and the corresponding drawings to clearly and completely describe the technical solution of the present invention. It is to be understood that the embodiments described are only some embodiments of the invention, and not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

The technical solutions provided by the embodiments of the present invention are described in detail below with reference to the accompanying drawings.

Referring to fig. 1 to 2, an embodiment of the present invention provides a high-efficiency cold accumulator, including a water tank 1, a medium feeding device 3, a medium discharging device 4, a first coil pipe 5 and a second coil pipe 6, where the water tank 1 is horizontally installed on the ground, the first coil pipe 5 and the second coil pipe 6 are respectively communicated with the medium feeding device 3 and the medium discharging device 4, the first coil pipe 5 is located in the water tank, the second coil pipe is also located in the water tank, the first coil pipe 5 and the second coil pipe 6 are arranged in a staggered manner, two ends of the first coil pipe 5 are respectively communicated with the medium feeding device 3 and the medium discharging device 4, and two ends of the second coil pipe 6 are respectively communicated with the medium feeding device 3 and the medium discharging device 4; first coil pipe 5 and the crisscross setting of second coil pipe 6 can improve the cooling efficiency to the water in the pond 1, the effect to the water cooling is better, the medium gets into first coil pipe 5 and second coil pipe 6 back respectively from medium feed arrangement 3, the medium by-20 degrees centigrade rise to-10 degrees centigrade, in-process at the intensification carries out the heat exchange, cool down to the water in the pond 1, cool down the water in the pond 1 after outwards discharging the medium through medium discharging device 4, cool down the back to water night, daytime can heat up to the water in the pond 1 because the rising of natural temperature, the heat of producing at the in-process of intensification can utilize the electricity generation.

Preferably, the medium feeding device 3 of the present invention includes a first feeding branch pipe 3, a second feeding branch pipe 32 and a feeding port 33, wherein the feeding port 33 is located on the water tank 1, the first feeding branch pipe 31 is communicated with the feeding port 33, the second feeding branch pipe 32 is located on the first feeding branch pipe 31, the second feeding branch pipe 32 is communicated with the first feeding branch pipe 31, the first feeding branch pipe 31 is communicated with one end of the second coil pipe 6, and the second feeding branch pipe 32 is communicated with one end of the first coil pipe 5; the medium enters from the feed inlet 33, is conveyed into the second coil 6 through the first feed branch pipe 31 respectively, is conveyed into the second feed branch pipe 32 through the first feed branch pipe 31 so as to move the medium into the first coil 5, is moved into the medium discharging device 4 by the first coil 5 and the second coil 6, and is moved forward by the first coil 5 and the second coil 6 so as to cool the water in the water pool 1.

Preferably, the medium discharging device 4 of the present invention includes a first discharging branch pipe 41, a second discharging branch pipe 42 and a discharging port 43, the discharging port 43 is located on the water tank 1 and located beside the feeding port 33, the first discharging branch pipe 41 is communicated with the discharging port 43, the second discharging branch pipe 42 is located on the first discharging branch pipe 41, the second discharging branch pipe 42 is communicated with the first discharging branch pipe 41, the first discharging branch pipe 41 is communicated with the other end of the first coil pipe 5, and the second discharging branch pipe 42 is communicated with the other end of the second coil pipe 6; after cooling water, when the medium is discharged, the medium in the first coil pipe 5 enters the discharge hole 43 through the first discharge branch pipe 41, the medium in the second coil pipe 6 enters the first discharge branch pipe 41 through the second discharge branch pipe 42, and the medium in the first discharge branch pipe 41 and the second discharge branch pipe 42 is discharged through the discharge hole 43.

Preferably, a coil pipe support frame 2 is arranged on the side wall of the water pool 1, the coil pipe support frame 2 is vertically arranged, and the first coil pipe 5 and the second coil pipe 6 are fixedly connected to the coil pipe support frame 2; the coil support frame 2 is used for fixing and mounting a first coil 5 and a second coil 6.

Preferably, the first coil pipe 5 and the second coil pipe 6 are both made of corrosion-resistant metal materials; the first coil pipe 5 and the second coil pipe 6 made of corrosion-resistant metal materials can prolong the service life of the first coil pipe 5 and the second coil pipe 6, and have good conductivity to cold air.

The working principle is as follows: the medium enters from the feeding hole 33, the medium is conveyed into the second coil 6 through the first feeding branch pipe 31 respectively, the medium is conveyed into the second feeding branch pipe 32 through the first feeding branch pipe 31 so as to move the medium into the first coil 5, the medium is moved into the medium discharging device 4 by the first coil 5 and the second coil 6, the medium is moved forward by the first coil 5 and the second coil 6 so as to uniformly cool the water in the water tank 1, after the water is cooled, when the medium is discharged, the medium in the first coil 5 enters the discharging hole 43 through the first discharging branch pipe 41, the medium in the second coil 6 enters the first discharging branch pipe 41 through the second discharging branch pipe 42 so as to convey the medium into the discharging hole 43, the medium in the first discharging branch pipe 41 and the second discharging branch pipe 42 is discharged outwards through the discharging hole 43, after the water is cooled at night, the water in the water pool 1 can be heated up due to the natural temperature rise in the daytime, and the heat generated in the heating process can be utilized for power generation.

The above description is only an example of the present invention, and is not intended to limit the present invention. Various modifications and changes may occur to those skilled in the art. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the scope of the claims of the present invention.

Claims

1. The utility model provides a high-efficient regenerator, its characterized in that, includes pond (1), medium feed arrangement (3), medium discharging device (4), first coil pipe (5) and second coil pipe (6), pond (1) horizontal installation is subaerial, first coil pipe (5) and second coil pipe (6) are linked together with medium feed arrangement (3) and medium discharging device (4) respectively, first coil pipe (5) are located the pond, the second coil pipe also is located the pond, first coil pipe (5) and second coil pipe (6) crisscross the setting, the both ends of first coil pipe (5) are linked together with medium feed arrangement (3) and medium discharging device (4) respectively, the both ends of second coil pipe (6) are linked together with medium feed arrangement (3) and medium discharging device (4) respectively.

2. A high-efficiency cold accumulator according to claim 1, characterized in that the medium feeding device (3) comprises a first feeding branch pipe (31), a second feeding branch pipe (32) and a feeding port (33), the feeding port (33) is located on the water tank (1), the first feeding branch pipe (31) is communicated with the feeding port (33), the second feeding branch pipe (32) is located on the first feeding branch pipe (31) and the second feeding branch pipe (32) is communicated with the first feeding branch pipe (31), the first feeding branch pipe (31) is communicated with one end of the second coil pipe (6), and the second feeding branch pipe (32) is communicated with one end of the first coil pipe (5).

3. A high-efficiency cold accumulator according to claim 2, characterized in that the medium discharging device (4) comprises a first discharging branch pipe (41), a second discharging branch pipe (42) and a discharging port (43), the discharging port (43) is located on the water tank (1) and beside the feeding port (33), the first discharging branch pipe (41) is communicated with the discharging port (43), the second discharging branch pipe (42) is located on the first discharging branch pipe (41), the second discharging branch pipe (42) is communicated with the first discharging branch pipe (41), the first discharging branch pipe (41) is communicated with the other end of the first coil pipe (5), and the second discharging branch pipe (42) is communicated with the other end of the second coil pipe (6).

4. The efficient cold accumulator according to claim 1, wherein a coil support frame (2) is arranged on the side wall of the water pool (1), the coil support frame (2) is vertically arranged, and the first coil (5) and the second coil (6) are fixedly connected to the coil support frame (2).

5. A high efficiency regenerator as claimed in claim 1 wherein the first coil (5) and the second coil (6) are made of corrosion resistant metal.