CN210531324U

CN210531324U - High-efficient combination formula oil gas cooler

Info

Publication number: CN210531324U
Application number: CN201921715961.5U
Authority: CN
Inventors: 李源
Original assignee: Wuxi Yafei Heat Exchanger Manufacturing Co ltd
Current assignee: Wuxi Yafei Heat Exchanger Manufacturing Co ltd
Priority date: 2019-10-14
Filing date: 2019-10-14
Publication date: 2020-05-15
Anticipated expiration: 2029-10-14

Abstract

The utility model is suitable for a cooler technical field provides a high-efficient combination formula oil gas cooler, including reposition of redundant personnel subassembly and heat transfer subassembly, the reposition of redundant personnel subassembly includes shell and shunt tubes, the shunt tubes is fixed in the inner wall of shell, the heat transfer subassembly includes radiator fan, condensing equipment and heat-conducting plate, radiator fan, condensing equipment and heat-conducting plate arrange along the flow direction of oil gas in proper order; in the in-process of using, at first carry out the forced air cooling through the oil gas that the heat dissipation tuber pipe flows to shunt tubes and inside and handle, afterwards, condensing equipment circulates the inside of shunt tubes with the condensate, utilize the condensate to carry out water treatment, simultaneously, still can be with the leading-in outside of the inside heat of shunt tubes through the heat-conducting plate, utilize the implementation of the radiating fan, the radiating efficiency of condenser and the three kinds of modes of heat-conducting plate, the radiating efficiency of cooler has been increased, and the work efficiency of cooler has indirectly been improved, and reduce the troublesome production of unnecessary.

Description

High-efficient combination formula oil gas cooler

Technical Field

The utility model belongs to the technical field of the cooler, especially, relate to a high-efficient combination formula oil gas cooler.

Background

Oil-air coolers are a type of oil cooling equipment commonly used in hydraulic systems and lubrication systems. The device can realize heat exchange between two fluid media with certain temperature difference, thereby achieving the purposes of reducing the oil temperature and ensuring the normal operation of the system.

The oil gas cooler on the existing market is carrying out the in-process that uses, and the inside cooling working method of cooler is comparatively single, and then influences the work efficiency of cooler to cause the trouble of unnecessary to produce.

SUMMERY OF THE UTILITY MODEL

The utility model provides a high-efficient combination formula oil gas cooler aims at solving the in-process that the oil gas cooler on the existing market is using, and the inside cooling working method of cooler is comparatively single, and then influences the work efficiency of cooler to cause the trouble production problem of unnecessary.

The utility model discloses a realize like this, a high-efficient combination formula oil gas cooler, including reposition of redundant personnel subassembly and heat exchange assemblies, the reposition of redundant personnel subassembly includes shell and shunt tubes, the shunt tubes is fixed in the inner wall of shell, heat exchange assemblies includes radiator fan, condensing equipment and heat-conducting plate, radiator fan, condensing equipment and heat-conducting plate are arranged along the flow direction of oil gas in proper order, just radiator fan fixed connection in the shell, condensing equipment fixed connection in the shell, just condensing equipment and heat-conducting plate all run through the shell.

Preferably, the flow dividing assembly further comprises a water inlet pipe and a water outlet pipe, wherein the water inlet pipe and the water outlet pipe are respectively fixedly connected to the two ends of the flow dividing pipe and penetrate through the shell.

Preferably, the shunt tubes comprise six branch tubes, a cavity which is independent from each other is formed between each branch tube, a heat collecting plate is accommodated in the cavity, and the heat collecting plate corresponds to the cooling fan.

Preferably, condensing equipment comprises condensing tank, circulating line and circulating water pump, circulating line runs through shell and shunt tubes, just circulating water pump is fixed in the condensing tank inner wall, and output fixed connection in circulating line, the condensing tank is fixed in the top of shell.

Preferably, the heat exchange assembly further comprises a heat transfer plate, the heat transfer plate is located inside the shunt pipe and fixedly connected to the heat conduction plate, and the heat conduction plate penetrates through the shell and the shunt pipe.

Preferably, the number of the heat transfer plates is six, and the heat transfer plates are respectively located inside the six branch pipes.

Preferably, the circulation pipe is formed in a bow shape and surrounds the inside of the casing.

Preferably, the interior of the condensation box is hollow and is communicated with the circulating pipeline, and condensate is contained in the condensation box.

Compared with the prior art, the beneficial effects of the utility model are that: the utility model discloses a high-efficient combination formula oil gas cooler, through setting up radiator fan, condensing equipment and heat-conducting plate, in the in-process that uses, the leading-in inside to the shunt tubes of oil gas, circulate in the inside of shunt tubes, afterwards, at first carry out the forced air cooling through the heat dissipation tuber pipe to shunt tubes and inside mobile oil gas and handle, afterwards, condensing equipment circulates the inside of shunt tubes with the condensate, utilize the condensate to carry out water treatment, and simultaneously, still can be with the leading-in outside of the inside heat of shunt tubes through the heat-conducting plate, utilize radiator fan, the implementation of the radiating mode of condensing equipment and three kinds of modes of heat-conducting plate, the radiating efficiency of cooler has been increased, and the work efficiency of cooler has been improved indirectly, and reduce the.

Drawings

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

fig. 2 is a schematic view of the internal structure of the present invention;

FIG. 3 is a schematic diagram of the structure of the heat-conducting plate of the present invention;

in the figure: 1. a flow diversion assembly; 11. a housing; 12. a water inlet pipe; 13. a drain pipe; 14. a shunt tube; 2. a heat exchange assembly; 21. a heat radiation fan; 22. a condenser tank; 23. a circulation pipe; 24. a heat conducting plate; 25. a heat collecting plate; 26. a water circulating pump; 27. a heat transfer plate.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more clearly understood, the present invention is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

Referring to fig. 1-3, the present invention provides a technical solution: the utility model provides a high-efficient combination formula oil gas cooler, including reposition of redundant personnel subassembly 1 and heat exchange assemblies 2, reposition of redundant personnel subassembly 1 includes shell 11 and shunt tubes 14, shunt tubes 14 are fixed in the inner wall of shell 11, heat exchange assemblies 2 includes radiator fan 21, condensing equipment and heat-conducting plate 24, radiator fan 21, condensing equipment and heat-conducting plate 24 are arranged along the flow direction of oil gas in proper order, and radiator fan 21 fixed connection is in shell 11, condensing equipment fixed connection is in shell 11, and condensing equipment and heat-conducting plate 24 all run through shell 11.

In this embodiment, the shunt tubes 14 are composed of a plurality of branch tubes, and a heat transfer plate 27 is disposed inside each branch tube, during use, oil gas flows inside the shunt tubes 14, when high-temperature oil gas passes through the heat transfer plate 27, the heat transfer plate 27 transfers heat in the oil gas to the inside of the heat transfer plate 24, and transfers the received heat to the outside through the heat transfer plate 24, and completes heat exchange treatment of the oil gas inside the shunt tubes 14.

In the present embodiment, during the use process, firstly, the worker guides the oil gas into the inside of the diversion pipe 14 through the water inlet pipe 12, the heat collection plate 25 is disposed between the plurality of branch pipes of the diversion pipe 14, the heat collection plate 25 is made of graphene, the heat collection plate 25 can concentrate heat, since the heat collection plate 25 corresponds to the heat dissipation fan 21, the heat absorbed by the heat collection plate 25 can be blown to the outside under the action of the heat dissipation fan 21, the air cooling heat dissipation treatment is indirectly performed on the diversion pipe 14 by using an air cooling method, then the oil gas after the air cooling treatment flows to the intersection of the diversion pipe 14 and the circulation pipe 23, at this time, the circulation water pump 26 starts to operate, the circulation water pump 26 delivers the condensate inside the condensation tank 22 to the inside of the circulation pipe 23 and flows inside the circulation pipe 23, and both ends of the circulation pipe 23 are communicated with the condensation tank 22, furthermore, the condensate flowing out of the interior of the condensation box 22 can flow back to the interior of the condensation box 22 through the other end of the circulation pipeline 23, the circulation pipeline 23 is arranged in an arc shape, the contact area between the circulation pipeline 23 and the shunt pipe 14 can be fully enlarged, the diameter of the circulation pipeline 23 is smaller than that of the branch pipe in the shunt pipe 14, the circulation pipeline 23 penetrates through the branch pipes one by one, the heat of oil gas in the shunt pipe 14 can be absorbed through the flowing of the condensate in the circulation pipeline 23, the oil gas in the shunt pipe 14 is condensed by using the condensate, then, when the oil gas passes through the interior of the heat transfer plate 27, the heat is guided into the heat conduction plate 24 through the heat transfer plate 27, and the heat is guided into the exterior through the heat conduction plate 24, and the heat dissipation efficiency of the cooler is increased by using the implementation of the heat dissipation modes of the heat, and indirectly improves the working efficiency of the cooler and reduces unnecessary trouble.

Further, the flow dividing assembly 1 further comprises a water inlet pipe 12 and a water outlet pipe 13, wherein the water inlet pipe 12 and the water outlet pipe 13 are respectively fixedly connected to two ends of the flow dividing pipe 14 and penetrate through the shell 11.

In the present embodiment, during use, the oil gas is introduced into the shunt pipe 14 through the inlet pipe 12, and after the oil gas in the shunt pipe 14 is subjected to heat dissipation and cooling treatment, the oil gas is discharged through the drain pipe 13.

Further, the dividing tube 14 is composed of six branch tubes, and a cavity is formed between each branch tube, wherein the cavity is independent from each other, a heat collecting plate 25 is accommodated inside the cavity, and the heat collecting plate 25 corresponds to the cooling fan 21.

In the present embodiment, the heat collecting plate 25 is made of graphene, the heat collecting plate 25 can concentrate heat, and since the heat collecting plate 25 corresponds to the heat dissipation fan 21, the heat absorbed by the heat collecting plate 25 can be blown to the outside by the heat dissipation fan 21, and the heat dissipation process of air cooling can be indirectly performed on the shunt pipe 14 by using an air cooling method.

Furthermore, the condensing device is composed of a condensing tank 22, a circulating pipeline 23 and a circulating water pump 26, the circulating pipeline 23 penetrates through the shell 11 and the shunt pipe 14, the circulating water pump 26 is fixed on the inner wall of the condensing tank 22, the output end of the circulating water pump is fixedly connected to the circulating pipeline 23, and the condensing tank 22 is fixed on the top of the shell 11; the interior of the condensation tank 22 is hollow and communicates with the circulation pipe 23, and the interior of the condensation tank 22 contains condensate.

In the present embodiment, the circulating water pump 26 delivers the condensate inside the condensation tank 22 to the inside of the circulating pipe 23, and flows inside the circulating pipe 23, and both ends of the circulating pipe 23 are communicated with the condensation tank 22, and the condensate flowing out of the inside of the condensation tank 22 also flows back to the inside of the condensation tank 22 through the other end of the circulating pipe 23, so that the heat of the oil gas inside the shunt pipe 14 can be absorbed through the flow of the condensate inside the circulating pipe 23, and the oil gas inside the shunt pipe 14 is condensed by the condensate.

Further, the heat exchange assembly 2 further comprises a heat transfer plate 27, the heat transfer plate 27 is located inside the shunt tube 14 and is fixedly connected to the heat conducting plate 24, and the heat conducting plate 24 penetrates through the shell 11 and the shunt tube 14; the number of the heat transfer plates 27 is six, and the heat transfer plates are respectively located inside the six branch pipes.

Further, the circulation duct 23 is formed in a bow shape and surrounds the inside of the housing 11.

In this embodiment, the circulation pipeline 23 is disposed in an arc shape, so that the contact area between the circulation pipeline 23 and the shunt pipe 14 can be sufficiently increased, and the oil and gas in the shunt pipe 14 can be cooled and radiated more effectively.

The above description is only exemplary of the present invention and should not be taken as limiting the scope of the present invention, as any modifications, equivalents, improvements and the like made within the spirit and principles of the present invention are intended to be included within the scope of the present invention.

Claims

1. The utility model provides a high-efficient combination formula oil gas cooler, includes reposition of redundant personnel subassembly (1) and heat exchange assemblies (2), reposition of redundant personnel subassembly (1) includes shell (11) and shunt tubes (14), shunt tubes (14) are fixed in the inner wall of shell (11), its characterized in that: heat exchange assemblies (2) are including radiator fan (21), condensing equipment and heat-conducting plate (24), radiator fan (21), condensing equipment and heat-conducting plate (24) are arranged in proper order along the flow direction of oil gas, just radiator fan (21) fixed connection in shell (11), condensing equipment fixed connection in shell (11), just condensing equipment and heat-conducting plate (24) all run through shell (11).

2. The highly efficient combined oil and gas cooler of claim 1, wherein: shunt subassembly (1) still includes inlet tube (12) and drain pipe (13), inlet tube (12) and drain pipe (13) respectively fixed connection in the both ends of shunt tubes (14), and all run through shell (11).

3. The highly efficient combined oil and gas cooler of claim 1, wherein: the heat collecting device is characterized in that the flow dividing pipe (14) is composed of six branch pipes, mutually independent cavities are formed between every two branch pipes, a heat collecting plate (25) is accommodated in each cavity, and the heat collecting plate (25) corresponds to the heat radiating fan (21).

4. The highly efficient combined oil and gas cooler of claim 1, wherein: condensing equipment comprises condensing tank (22), circulating line (23) and circulating water pump (26), circulating line (23) run through shell (11) and shunt tubes (14), just circulating water pump (26) are fixed in condensing tank (22) inner wall, and output fixed connection in circulating line (23), condensing tank (22) are fixed in the top of shell (11).

5. A high efficiency combined oil and gas cooler as set forth in claim 3, wherein: the heat exchange assembly (2) further comprises a heat transfer plate (27), the heat transfer plate (27) is located inside the shunt pipe (14) and fixedly connected to the heat conduction plate (24), and the heat conduction plate (24) penetrates through the shell (11) and the shunt pipe (14).

6. The highly efficient combined oil and gas cooler of claim 5, wherein: the number of the heat transfer plates (27) is six, and the heat transfer plates are respectively positioned inside the six branch pipes.

7. The highly efficient combined oil and gas cooler of claim 4, wherein: the circulating pipeline (23) is in a bow shape and surrounds the inside of the shell (11).

8. The highly efficient combined oil and gas cooler of claim 4, wherein: the interior of the condensation tank (22) is hollow and is communicated with the circulating pipeline (23), and condensate is contained in the condensation tank (22).