CN211261362U

CN211261362U - Double-spiral coil pipe equipment capable of improving heat dissipation efficiency

Info

Publication number: CN211261362U
Application number: CN201921937471.XU
Authority: CN
Inventors: 朱敏军; 滕宗林
Original assignee: Famous Wat Klimatec Co ltd
Current assignee: Famous Wat Klimatec Co ltd
Priority date: 2019-11-12
Filing date: 2019-11-12
Publication date: 2020-08-14
Anticipated expiration: 2029-11-12

Abstract

The utility model relates to a coil pipe equipment technical field just discloses a double helix coil pipe equipment that improves radiating efficiency. This improve radiating efficiency's double helix coil pipe equipment, including first spiral coil pipe, second spiral coil pipe, first heat abstractor and second heat abstractor, the outer circumference cover of first spiral coil pipe is equipped with second spiral coil pipe, first heat abstractor is installed to first spiral coil pipe's bottom. This improve radiating efficiency's double helix coil pipe equipment, through spiral outer tube among the second heat abstractor, the air current chamber, first bracing piece, a through-hole, the condenser pipe, cooperation setting between spiral inner tube and the second bracing piece, when the rivers that flow into first spiral coil pipe and second spiral coil pipe from the outlet pipe flow into spiral inner tube inside, the condenser pipe of spiral inner tube inside carries out the secondary cooling heat dissipation to it, outside air current chamber will blow to the outer periphery of spiral inner tube from the air that the through-hole flowed in, carry out the heat dissipation in many places, thereby radiating efficiency has been improved.

Description

Double-spiral coil pipe equipment capable of improving heat dissipation efficiency

Technical Field

The utility model relates to a coil pipe equipment technical field specifically is a improve double helix coil pipe equipment of radiating efficiency.

Background

The evaporator and the condenser are core components for refrigeration, a common evaporator coil surrounds the inner container of the refrigerator and the heat-insulating layer, and the evaporator is attached to the outer wall of the inner container for heat conduction, so that heat exchange is carried out between the refrigerant liquid flowing in the evaporator and the inner container. The evaporator coil is generally divided into various systems of evaporators in a copper core coil mode, evaporators in various shapes can be arranged in a limited space, and the evaporators spirally wind the maximum heat exchange area in a minimum space.

However, the existing double-spiral coil equipment has the following problems that firstly, the heat dissipation efficiency is low, the refrigeration speed is low, and the refrigeration efficiency is low, so that the heat exchange efficiency of an evaporator and a condenser is seriously influenced.

SUMMERY OF THE UTILITY MODEL

The utility model provides a not enough to prior art, the utility model provides an improve double helix coil pipe equipment of radiating efficiency possesses the improvement radiating efficiency, and refrigeration effect advantage such as good has solved the radiating efficiency low, leads to the slow problem of refrigeration speed, and refrigeration efficiency is low moreover, has seriously influenced the problem of the heat exchange efficiency of evaporimeter and condenser.

The utility model provides a technical scheme that its technical problem adopted is: the utility model provides an improve radiating efficiency's double helix coil pipe equipment, includes first spiral coil pipe, second spiral coil pipe, first heat abstractor and second heat abstractor, the outer circumference cover of first spiral coil pipe is equipped with second spiral coil pipe, first heat abstractor is installed to first spiral coil pipe's bottom, first spiral coil pipe all installs second heat abstractor with second spiral coil pipe's inside.

The first heat dissipation device comprises a heat dissipation box, the heat dissipation box is communicated with the bottom end of the first spiral coil pipe, the bottom middle end of the heat dissipation box is communicated with a water inlet pipe, the top middle end of the heat dissipation box is communicated with a water outlet pipe, the left side middle of the heat dissipation box is communicated with a cold water pipe, the right side middle end of the heat dissipation box is communicated with a hot water pipe, a first partition plate is fixedly mounted at the top in the heat dissipation box, a second partition plate is fixedly mounted at the bottom in the heat dissipation box, a support plate is fixedly mounted at the right side of the hot cold water pipe, and a baffle is folded relative to one end of the cold water pipe by the.

The second heat dissipation device comprises a spiral outer pipe, the spiral outer pipe is arranged on the outer layer of the first spiral coil pipe, a through hole is formed in the circumference of the spiral outer pipe, a first supporting rod is fixedly arranged in the circumference of the spiral outer pipe, the first supporting rod is fixedly connected with a spiral inner pipe relative to one end of the spiral outer pipe, a second supporting rod is fixedly arranged in the circumference of the spiral inner pipe, and the second supporting rod is fixedly connected with a condensation pipe relative to one end of the spiral inner pipe.

Furthermore, the bottom ends of the first spiral coil and the second spiral coil are communicated with water outlet pipes, and the water outlet pipes are three-way pipes.

Furthermore, both ends of the first partition plate and the second partition plate are fixedly installed on the inner wall of the heat dissipation box, and a cavity between the first partition plate and the second partition plate is a heat dissipation cavity.

Further, the quantity of turning over the baffle is a plurality of, and turns over the equal fixedly connected with backup pad in both ends of baffle, and logical groove has been seted up at the middle part of backup pad, and leads to the diameter of groove and the pipe diameter phase-match of cold water pipe.

Furthermore, an airflow cavity is arranged between the spiral outer pipe and the spiral inner pipe, a plurality of through holes are formed in the circumference of the spiral outer pipe, and the through holes are communicated with the outside air.

Furthermore, the number of the first supporting rods and the number of the second supporting rods are three, the angle between every two adjacent first supporting rods is 120 degrees, and the angle between every two adjacent second supporting rods is 120 degrees.

Furthermore, the outer diameter of the condensation pipe is smaller than one half of the inner diameter of the spiral inner pipe, and the circle centers of the condensation pipe, the spiral inner pipe and the spiral outer pipe are overlapped.

The utility model has the advantages that:

1. this improve radiating efficiency's double helix coil pipe equipment, through the heat dissipation case among the first heat abstractor, the inlet tube, the outlet pipe, the cold water pipe, the hot-water line, the second division board, first division board, backup pad and the cooperation setting between the baffle of rolling over, when flowing in rivers from the inlet tube, the inlet tube sends rivers through the heat dissipation case, through cold water in the cold water pipe, make it flow in the heat dissipation intracavity, roll over the velocity of flow that the baffle slows down cold water through equipment, make its and inlet tube fully contact, increase cooling's effect, and the pipeline of inlet tube runs through the inside of whole heat dissipation case, make the inlet tube can fully contact with cold water, increase radiating efficiency.

2. This improve radiating efficiency's double helix coil pipe equipment, through spiral outer tube among the second heat abstractor, the air current chamber, first bracing piece, a through-hole, the condenser pipe, cooperation setting between spiral inner tube and the second bracing piece, when the rivers that flow into first spiral coil pipe and second spiral coil pipe from the outlet pipe flow in the spiral inner tube, the condenser pipe of spiral inner tube inside carries out the secondary cooling heat dissipation to it, outside air current chamber will blow to the outer periphery of spiral inner tube from the air that the through-hole flowed in, carry out the heat dissipation in many places, thereby radiating efficiency has been improved.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below.

FIG. 1 is a perspective view of the present invention;

fig. 2 is a schematic structural view of a first heat dissipation device of the present invention;

fig. 3 is a schematic structural view of a second heat dissipation device of the present invention.

Description of reference numerals: 1-a first spiral coil pipe, 2-a second spiral coil pipe, 3-a first heat dissipation device, 301-a heat dissipation box, 302-a water inlet pipe, 303-a water outlet pipe, 304-a cold water pipe, 305-a hot water pipe, 306-a second partition plate, 307-a first partition plate, 308-a support plate, 309-a folding baffle, 4-a second heat dissipation device, 401-a spiral outer pipe, 402-an air flow cavity, 403-a first support rod, 404-a through hole, 405-a condensation pipe, 406-a spiral inner pipe and 407-a second support rod.

Detailed Description

The technical solution in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention.

Referring to fig. 1-3, a double-spiral-coil apparatus for improving heat dissipation efficiency includes a first spiral coil 1, a second spiral coil 2, a first heat dissipation device 3 and a second heat dissipation device 4, wherein the second spiral coil 2 is sleeved on an outer circumference of the first spiral coil 1, the first heat dissipation device 3 is installed at a bottom of the first spiral coil 1, and the second heat dissipation device 4 is installed inside both the first spiral coil 1 and the second spiral coil 2.

The first heat dissipation device 3 comprises a heat dissipation box 301, the heat dissipation box 301 is communicated with the bottom end of the first spiral coil 1, the middle end of the bottom of the heat dissipation box 301 is communicated with a water inlet pipe 302, the middle end of the top of the heat dissipation box 301 is communicated with a water outlet pipe 303, the bottom ends of the first spiral coil 1 and the second spiral coil 2 are communicated with water outlet pipes 303, the water outlet pipes 303 are three-way pipes, the middle part of the left side of the heat dissipation box 301 is communicated with a cold water pipe 304, the middle end of the right side of the heat dissipation box 301 is communicated with a hot water pipe 305, a first partition plate 307 is fixedly installed at the top in the heat dissipation box 301, two ends of the first partition plate 307 and the second partition plate 306 are fixedly installed on the inner wall of the heat dissipation box 301, a cavity between the first partition plate 307 and the second partition plate 306 is a heat dissipation cavity, a second partition plate 306 is fixedly installed at the bottom in the heat dissipation box 301, a support, the number of the baffle plates 309 is a plurality of, the two ends of the baffle plates 309 are fixedly connected with the supporting plates 308, the middle parts of the supporting plates 308 are provided with through grooves, and the diameters of the through grooves are matched with the pipe diameters of the cold water pipes 304.

The second heat dissipation device 4 includes a spiral outer tube 401, an airflow cavity 402 is disposed between the spiral outer tube 401 and the spiral inner tube 406, a plurality of through holes 404 are disposed on the circumference of the spiral outer tube 401, the through holes 404 are communicated with the outside air, the spiral outer tube 401 is disposed on the outer layer of the first spiral coil 1, the through holes 404 are disposed on the circumference of the spiral outer tube 401, a first support rod 403 is fixedly mounted in the circumference of the spiral outer tube 401, the spiral inner tube 406 is fixedly connected to one end of the first support rod 403 opposite to the spiral outer tube 401, the outer diameter of the condenser tube 405 is smaller than one half of the inner diameter of the spiral inner tube 406, the centers of the condenser tube 405, the spiral inner tube 406 and the spiral outer tube 401 are overlapped, a second support rod 407 is fixedly mounted in the circumference of the spiral inner tube 406, the number of the first support rod 403 and the second support rod 407 is three, and the angle, the angle between every two adjacent second support bars 407 is 120 degrees, and the condensing tube 405 is fixedly connected to one end of each second support bar 407 relative to the spiral inner tube 406.

When the heat dissipation device is used, through the matching arrangement among the heat dissipation box 301, the water inlet pipe 302, the water outlet pipe 303, the cold water pipe 304, the hot water pipe 305, the second partition plate 306, the first partition plate 307, the support plate 308 and the baffle plate 309 in the first heat dissipation device 3, when water flows in from the water inlet pipe 302, the water flow is sent to the heat dissipation box 301 through the water inlet pipe 302, the cold water flows into the heat dissipation cavity through the cold water in the cold water pipe 304, the flow rate of the cold water is reduced through the equipment baffle plate 309, the cold water is fully contacted with the water inlet pipe 302, the cooling effect is improved, the pipeline of the water inlet pipe 302 penetrates through the inside of the whole heat dissipation box 301, the water inlet pipe 302 can be fully contacted with the cold water, the heat dissipation efficiency is improved, the water flows into the spiral inner pipe 406 through the matching arrangement among the spiral outer pipe 401, the air flow cavity 402, the first support rod 403, the through hole 404, the condensation pipe 405, the spiral inner pipe 406 and the second When the air flows into the spiral inner tube 406, the condensation tube 405 inside the spiral inner tube 406 cools the air for the second time, and the external airflow cavity 402 blows the air flowing from the through hole 404 to the outer circumferential surface of the spiral inner tube 406 to perform heat dissipation at multiple positions, so that the heat dissipation efficiency is improved.

The previous description of the disclosed embodiments is provided to enable any person skilled in the art to make or use the present invention. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the invention. Thus, the present invention is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims

1. The utility model provides an improve radiating efficiency's double helix coil pipe equipment, includes first spiral coil pipe (1), second spiral coil pipe (2), first heat abstractor (3) and second heat abstractor (4), its characterized in that: a second spiral coil (2) is sleeved on the outer circumference of the first spiral coil (1), a first heat dissipation device (3) is installed at the bottom of the first spiral coil (1), and second heat dissipation devices (4) are installed inside the first spiral coil (1) and the second spiral coil (2);

the first heat dissipation device (3) comprises a heat dissipation box (301), the heat dissipation box (301) is communicated with the bottom end of the first spiral coil (1), the middle end of the bottom of the heat dissipation box (301) is communicated with a water inlet pipe (302), the middle end of the top of the heat dissipation box (301) is communicated with a water outlet pipe (303), the middle of the left side of the heat dissipation box (301) is communicated with a cold water pipe (304), the middle end of the right side of the heat dissipation box (301) is communicated with a hot water pipe (305), a first partition plate (307) is fixedly installed at the top in the heat dissipation box (301), a second partition plate (306) is fixedly installed at the bottom in the heat dissipation box (301), a support plate (308) is fixedly installed at the right side of the cold water pipe (304), and a baffle plate (309) is fixedly connected to one end, opposite to the;

second heat abstractor (4) are including spiral outer tube (401), the skin at first spiral coil pipe (1) is established in spiral outer tube (401), through-hole (404) have been seted up on the circumference of spiral outer tube (401), fixed mounting has first bracing piece (403) in the circumference of spiral outer tube (401), first bracing piece (403) are for the one end fixedly connected with spiral inner tube (406) of spiral outer tube (401), fixed mounting has second bracing piece (407) in the circumference of spiral inner tube (406), second bracing piece (407) are for the one end fixedly connected with condenser pipe (405) of spiral inner tube (406).

2. The apparatus of claim 1, wherein the double spiral coil pipe is configured to increase heat dissipation efficiency: the bottom ends of the first spiral coil (1) and the second spiral coil (2) are communicated with water outlet pipes (303), and the water outlet pipes (303) are three-way pipes.

3. The apparatus of claim 1, wherein the double spiral coil pipe is configured to increase heat dissipation efficiency: the two ends of the first partition plate (307) and the second partition plate (306) are fixedly mounted on the inner wall of the heat dissipation box (301), and a cavity between the first partition plate (307) and the second partition plate (306) is a heat dissipation cavity.

4. The apparatus of claim 1, wherein the double spiral coil pipe is configured to increase heat dissipation efficiency: the number of the baffle plates (309) is a plurality of, the two ends of the baffle plates (309) are fixedly connected with the supporting plates (308), the middle parts of the supporting plates (308) are provided with through grooves, and the diameters of the through grooves are matched with the pipe diameters of the cold water pipes (304).

5. The apparatus of claim 1, wherein the double spiral coil pipe is configured to increase heat dissipation efficiency: an airflow cavity (402) is arranged between the spiral outer pipe (401) and the spiral inner pipe (406), a plurality of through holes (404) are formed in the circumference of the spiral outer pipe (401), and the through holes (404) are communicated with the outside air.

6. The apparatus of claim 1, wherein the double spiral coil pipe is configured to increase heat dissipation efficiency: the number of the first supporting rods (403) and the number of the second supporting rods (407) are three, the angle between every two adjacent first supporting rods (403) is 120 degrees, and the angle between every two adjacent second supporting rods (407) is 120 degrees.

7. The apparatus of claim 1, wherein the double spiral coil pipe is configured to increase heat dissipation efficiency: the outer diameter of the condensation pipe (405) is smaller than one half of the inner diameter of the spiral inner pipe (406), and the circle centers of the condensation pipe (405), the spiral inner pipe (406) and the spiral outer pipe (401) are overlapped.