CN215930622U - Ultrasonic nano-wave heat exchange device - Google Patents
Ultrasonic nano-wave heat exchange device Download PDFInfo
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- CN215930622U CN215930622U CN202122468638.6U CN202122468638U CN215930622U CN 215930622 U CN215930622 U CN 215930622U CN 202122468638 U CN202122468638 U CN 202122468638U CN 215930622 U CN215930622 U CN 215930622U
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Abstract
The utility model discloses an ultrasonic nano-wave heat exchange device, which comprises a cylinder body, a first medium port, a second medium port, a first water port and a second water port, wherein more than one layer of spiral efficient coil pipes are arranged in the cylinder body, two pipe ports of each layer of spiral coil pipe are respectively communicated with a central pipe and a side pipe, the central pipe is vertically arranged on the central axis of the cylinder body, the upper end of the central pipe penetrates out of the top of the cylinder body and is provided with an opening as the first medium port, the side pipe is vertically arranged at one side in the cylinder body, the lower end of the side pipe penetrates out of the lower part of the cylinder body and is provided with an opening as the second medium port.
Description
Technical Field
The utility model belongs to the technical field of heat exchange equipment, and particularly relates to an ultrasonic nano-wave heat exchange device.
Background
The heat exchanger is widely applied in various industries, the existing heat exchanger generally adopts a plurality of steel pipes as a water flowing pipeline from top to bottom, working media are arranged in a shell, the design and manufacturing cost is high, the heat exchanger belongs to a pressure container, the manufacturing process is complex, potential safety hazards exist, meanwhile, the heat exchange effect is poor due to the fact that automatic descaling cannot be carried out, and impurities in water can be deposited on the inner wall of the pipeline to influence use; when the low-temperature refrigerant flows in the cylinder, a small amount of refrigeration oil is inevitably carried in the refrigerant, so that the small amount of oil can be separated in the heat exchange process, and the refrigeration oil can be collected in the cylinder to influence the heat exchange efficiency.
SUMMERY OF THE UTILITY MODEL
The utility model aims to overcome the defects of the prior art and provide an ultrasonic nano-wave heat exchange device which has high heat exchange efficiency, is convenient to clean and use and has long service life.
The utility model aims to realize the ultrasonic nano-wave heat exchange device which comprises a cylinder body, a first medium port, a second medium port, a first water gap and a second water gap and is characterized in that more than one layer of spiral efficient coil pipes are arranged in the cylinder body, two pipe ports of each layer of spiral coil pipe are respectively communicated with a central pipe and a side pipe, the central pipe is vertically arranged on the central axis of the cylinder body, the upper end of the central pipe penetrates out of the top of the cylinder body, an opening is used as the first medium port, the side pipe is vertically arranged on one side in the cylinder body, the lower end of the side pipe penetrates out of the lower part of the cylinder body, and the opening is used as the second medium port.
In order to further achieve the object of the present invention, a support frame for supporting the spiral coil may be provided below the lowermost spiral coil.
In order to further realize the purpose of the utility model, more than one layer of oil circulation spiral coil pipes are arranged at the middle lower part in the cylinder body, two pipe orifices of each layer of oil circulation spiral coil pipes are respectively communicated with a central oil pipe and a side oil pipe, the central oil pipe is vertically arranged on the central axis of the cylinder body, the upper end of the central oil pipe penetrates through the side part of the cylinder body and is provided with an opening as an oil outlet, the side oil pipe is vertically arranged at one side in the cylinder body, the lower end of the side oil pipe penetrates through the side of the cylinder body and is provided with an opening as an oil inlet, and the oil inlet is lower than the oil outlet.
In order to further achieve the object of the present invention, an oil pipe support frame for supporting the oil circulating spiral coil may be provided below the lowermost oil circulating spiral coil.
In order to further achieve the purpose of the utility model, an ultrasonic nano-wave generator can be arranged on the lower surface of the support frame or the oil pipe support frame.
In order to further achieve the purpose of the utility model, the lower end of the central tube may be connected and communicated with an oil discharge tube extending out of the cylinder body.
In order to further realize the aim of the utility model, a deflation valve, a pressure sensor and a liquid level controller are arranged at the top of the cylinder body, and temperature sensors are arranged on the first water port, the second water port and the cylinder body.
In order to further achieve the purpose of the utility model, the cylinder body can be provided with an insulating layer.
In order to further realize the aim of the utility model, a sewage draining outlet can be arranged at the bottom of the cylinder body.
In order to further achieve the purpose of the utility model, a water replenishing port can be arranged at the bottom of the cylinder body.
Compared with the prior art, the utility model has the following remarkable characteristics and positive effects: the utility model adopts the layered arrangement of the multilayer spiral coil pipes, the manufacture and the installation are convenient and fast, and the heat exchange efficiency is high; the spiral coil pipe, the support frame below the oil circulation spiral coil pipe and the oil pipe support frame can respectively support the spiral coil pipe and the oil circulation spiral coil pipe, so that the two spiral coil pipes can not sink and deform for a long time, the use effect is ensured, meanwhile, the support frame is convenient for mounting an ultrasonic nano generator, the ultrasonic nano generator enables water in a cylinder body to generate micro bubbles and vibration flow, the heat exchange efficiency is improved, and meanwhile, the ultrasonic nano generator has the effects of disinfection and sterilization and is compact in structure, the ultrasonic nano generator can avoid the problem of scaling, and the heat efficiency is ensured; the heat exchange process can be monitored and controlled at any time by adopting the air release valve, the pressure sensor, the liquid level controller and the temperature sensor; the heat-insulating layer is arranged on the barrel body, so that heat loss and efficiency influence are avoided; the sewage outlet at the bottom of the cylinder body can discharge impurity precipitates and water scales in water, so that the heat efficiency is kept; the bottom of the cylinder body is provided with a water replenishing port, and the water replenishing port can be controlled by a liquid level controller to be automatically replenished into the cylinder body continuously through the water replenishing port to reciprocate circularly.
Drawings
FIG. 1 is a schematic diagram of a structure of the present invention.
Fig. 2 is a schematic structural diagram of the spiral coil of the present invention.
Fig. 3 is another schematic structural diagram of the present invention.
FIG. 4 is a schematic view of another embodiment of the present invention.
In the figure: 1. the device comprises a cylinder body, 2, a first water gap, 3, a second water gap, 4, a spiral coil pipe, 5, a central pipe, 6, a side pipe, 7, a first medium port, 8, a second medium port, 9, a support frame, 10, an ultrasonic nano-wave generator, 11, an oil circulation spiral coil pipe, 12, a central oil pipe, 13, a side oil pipe, 14, an oil outlet, 15, an oil inlet, 16, an oil pipe support frame, 17, an oil discharge pipe, 18, a gas release valve, 19, a pressure sensor, 20, a liquid level controller, 21, a temperature sensor, 22, a heat insulation layer, 23, a sewage discharge port, 24 and a water replenishing port.
Detailed Description
An ultrasonic nanometer wave heat exchange device, refer to fig. 1 and fig. 2, a first water gap 2 is arranged at the upper part of a cylinder 1, a second water gap 3 is arranged at the lower part of the cylinder 1, more than one layer of spiral coil 4 is arranged in the cylinder 1, the layers of the spiral coil 4 are determined according to requirements and space in the cylinder 1, in this embodiment, 29 layers of spiral coils 4 are adopted, pipe orifices at two ends of each layer of spiral coil 4 are respectively communicated and connected with a central pipe 5 and a side pipe 6, the central pipe 5 is vertically arranged on a central axis in the cylinder 1, the upper end of the central pipe penetrates through the top of the cylinder 1 and is opened to serve as a first medium port 7, the side pipe 6 is vertically arranged at one side in the cylinder 1, the lower end of the side pipe penetrates through the lower part of the cylinder 1 and is opened to serve as a second medium port 8, the spiral coil 4 serves as a flow channel of a refrigerant or a high-temperature high-pressure medium, and serves as refrigeration when the refrigerant is arranged in the spiral coil 4, the second medium port 8 is used as a refrigerant inlet, the first medium port 7 is used as a refrigerant outlet, the first water port 2 is used as a water inlet, the second water port 3 is used as a water outlet, when high-temperature and high-pressure media exist in the spiral coil 4, the spiral coil is used for heating, the second medium port 8 is used as a high-temperature and high-pressure medium outlet, the first medium port 7 is used as a high-temperature and high-pressure medium inlet, the first water port 2 is used as a water outlet, and the second water port 3 is used as a water inlet.
Referring to fig. 3, a support frame 9 for supporting the spiral coil 4 is arranged below the spiral coil 4 at the lowest layer, an ultrasonic nano-wave generator 10 is arranged on the lower surface of the support frame 9, an oil discharge pipe 17 extending out of the cylinder 1 is connected and communicated with the lower end of the central pipe 5, a deflation valve 18, a pressure sensor 19 and a liquid level controller 20 are arranged at the top of the cylinder 1, a temperature sensor 21 is respectively arranged on the first water port 2, the second water port 3 and the cylinder 1, the cylinder 1 is provided with a heat insulation layer 22, and a sewage draining port 23 and a water replenishing port 24 are arranged at the bottom of the cylinder 1.
Referring to fig. 4, more than one layer of oil circulation spiral coils 11 are arranged at the middle lower part in the cylinder 1, two pipe orifices of each layer of oil circulation spiral coils 11 are respectively communicated with a central oil pipe 12 and a side oil pipe 13, the central oil pipe 12 is vertically arranged on the central axis in the cylinder 1, the upper end of the central oil pipe penetrates through the side part of the cylinder 1 and is provided with an opening as an oil outlet 14, the side oil pipe 13 is vertically arranged at one side in the cylinder 1, the lower end of the side oil pipe penetrates through the side of the cylinder 1 and is provided with an oil inlet 15, the oil inlet 15 is lower than the oil outlet 14, an oil pipe support frame 16 for supporting the oil circulation spiral coils 11 is arranged below the lowest layer of oil circulation spiral coils 11, and the lower surface of the oil pipe support frame 16 is provided with an ultrasonic nano-wave generator 10.
Claims (10)
1. The utility model provides an supersound nanometer ripples heat exchange device, includes the barrel, first medium mouth, second medium mouth, first mouth of a river, second mouth of a river, is provided with the high-efficient coil pipe of screw-tupe more than the one deck in the barrel of characterized by, and two mouths of a pipe of every layer of spiral coil pipe communicate with center tube, side pipe respectively, and the center tube is vertical to be set up on the barrel central axis, and its upper end is worn out the barrel top and the opening as first medium mouth, and the side pipe is vertical to be set up one side in the barrel, and its lower extreme is worn out barrel lower part and opening as second medium mouth.
2. The ultrasonic nano-wave heat exchange device according to claim 1, wherein a support frame for supporting the spiral coil is provided below the lowermost spiral coil.
3. The ultrasonic nano-wave heat exchange device according to claim 1, wherein more than one layer of oil circulation spiral coils are arranged at the middle lower part in the cylinder, two pipe orifices of each layer of oil circulation spiral coils are respectively communicated with a central oil pipe and a side oil pipe, the central oil pipe is vertically arranged on the central axis of the cylinder, the upper end of the central oil pipe penetrates through the side part of the cylinder and is opened to serve as an oil outlet, the side oil pipe is vertically arranged at one side in the cylinder, the lower end of the side oil pipe penetrates through the side of the cylinder and is opened to serve as an oil inlet, and the oil inlet is lower than the oil outlet.
4. The ultrasonic nano-wave heat exchange device according to claim 1, wherein an oil pipe support frame for supporting the oil circulation spiral coil is disposed below the lowermost oil circulation spiral coil.
5. The ultrasonic nano-wave heat exchange device according to claim 2 or 4, wherein the ultrasonic nano-wave generator is mounted on the lower surface of the support frame or the oil pipe support frame.
6. The ultrasonic nano-wave heat exchange device according to claim 1, wherein the lower end of the central tube is connected and communicated with an oil discharge tube extending out of the cylinder body.
7. The ultrasonic nano-wave heat exchange device according to claim 1, wherein a gas release valve, a pressure sensor and a liquid level controller are arranged at the top of the cylinder, and temperature sensors are arranged on the first water port, the second water port and the cylinder.
8. The ultrasonic nano-wave heat exchange device according to claim 1, wherein the cylinder is provided with an insulating layer.
9. The ultrasonic nano-wave heat exchange device of claim 1, wherein a drain outlet is provided at the bottom of the cylinder.
10. The ultrasonic nano-wave heat exchange device according to claim 1, wherein a water replenishing port is provided at the bottom of the cylinder.
Priority Applications (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN202122468638.6U CN215930622U (en) | 2021-10-14 | 2021-10-14 | Ultrasonic nano-wave heat exchange device |
Applications Claiming Priority (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN202122468638.6U CN215930622U (en) | 2021-10-14 | 2021-10-14 | Ultrasonic nano-wave heat exchange device |
Publications (1)
| Publication Number | Publication Date |
|---|---|
| CN215930622U true CN215930622U (en) | 2022-03-01 |
Family
ID=80407731
Family Applications (1)
| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| CN202122468638.6U Active CN215930622U (en) | 2021-10-14 | 2021-10-14 | Ultrasonic nano-wave heat exchange device |
Country Status (1)
| Country | Link |
|---|---|
| CN (1) | CN215930622U (en) |
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2021
- 2021-10-14 CN CN202122468638.6U patent/CN215930622U/en active Active
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