A water cooling system for a phase modifier with high cooling efficiency

Abstract

The utility model discloses a kind of water cooling systems for phase-modulating camera of cooling efficiency, belong to phase-modulating camera technical field, it includes phase-modulating camera casing, the left side of the phase-modulating camera casing is provided with sealing cover, spiral waterway is penetrated in the inside of the sealing cover and is abutted with the inner wall of phase-modulating camera casing, the left side of the spiral waterway is provided with cooling cooling device, the left side of the phase-modulating camera casing is provided with cooling water tank, the upper surface of the cooling water tank is fixedly installed with cooling water pump. The water cooling system for phase-modulating camera of cooling efficiency, by setting driving motor and driving shaft bring drive fan blade and rotating disc and rotating fan blade rotation cooling operation to annular heat dissipation cylinder, air flow is accelerated, cooperate with radiating fin can quickly spiral waterway in cooling water carried heat dissipate to outside, effectively reduce cooling water temperature, improve the cooling effect to phase-modulating camera, improve the convenience of people using phase-modulating camera.

Description

Technical Field

[0001] This utility model belongs to the field of camera condenser technology, specifically a water-cooling system for camera condensers with improved cooling efficiency. Background Technology

[0002] Synchronous condensers are a type of synchronous motor operating under special conditions. When applied to power systems, they can automatically increase reactive power output when the grid voltage drops and absorb reactive power when the grid voltage rises, in order to maintain voltage, improve power system stability, and enhance power supply quality. Synchronous condensers generate a large amount of heat during operation, and their cooling is crucial for their normal operation, necessitating effective heat dissipation methods. Currently, existing synchronous condensers generally use a spiral cooling water circuit for cooling. However, this method causes the water in the cooling water circuit to gradually heat up, failing to achieve the ideal cooling effect and resulting in low cooling efficiency, thus reducing the ease of use for synchronous condensers. Utility Model Content

[0003] (a) Technical problems to be solved

[0004] In order to overcome the above-mentioned defects of the prior art, this utility model provides a water cooling system for the condenser with high cooling efficiency. This solves the problem that the cooling method of the condenser causes the water in the cooling water circuit to gradually heat up, resulting in the inability to achieve the ideal cooling and heat dissipation effect of the condenser, which leads to low cooling efficiency and reduces the convenience of using the condenser.

[0005] (II) Technical Solution

[0006] To achieve the above objectives, this utility model provides the following technical solution: a water-cooled system for a high-efficiency camera condenser, comprising a camera condenser housing, a sealing cover provided on the left side of the camera condenser housing, a spiral water channel penetrating through the interior of the sealing cover and abutting against the inner wall of the camera condenser housing, a cooling device provided on the left side of the spiral water channel, a cooling water tank provided on the left side of the camera condenser housing, a cooling water pump fixedly installed on the upper surface of the cooling water tank, a suction pipe penetrating inside the cooling water tank being connected to the input end of the cooling water pump, an outlet pipe being connected to the output end of the cooling water pump, and a return water pipe being connected to the left side of the cooling water tank.

[0007] As a further embodiment of this utility model: a heat-conducting probe is fixedly installed on the left side of the cooling water tank, and a cooling fan is fixedly installed on the upper surface of the heat-conducting probe.

[0008] As a further embodiment of this utility model: the cooling and heat dissipation device includes an annular heat dissipation cylinder fixedly installed on the left side of the spiral water channel, heat dissipation fins fixedly installed on the outer surface of the annular heat dissipation cylinder, a drive motor fixedly installed on the left side of the sealing cover, a drive shaft fixedly installed at the output end of the drive motor, rotating fan blades fixedly installed on the outer surface of the drive shaft, a circular bracket connected to the inner wall of the annular heat dissipation cylinder fixedly installed on the outer surface of the drive shaft, a rotating circular plate fixedly installed at the left end of the drive shaft, rotating fan blades fixedly installed on the inner side of the rotating circular plate, and an L-shaped positioning plate slidably provided on the left side of the rotating circular plate and connected to the left side of the sealing cover.

[0009] As a further embodiment of this utility model: the top of both the outlet pipe and the return pipe are connected to the right side of the annular heat sink.

[0010] As a further embodiment of this utility model: an annular sliding groove is provided on the left side of the rotating circular plate, and a sliding column is fixedly installed on the inner side of the L-shaped positioning plate, with the annular sliding groove and the sliding column being slidably connected.

[0011] As a further embodiment of this utility model: the number of heat dissipation fins is twenty sets, and rectangular ventilation holes are opened on the outer side of each of the twenty sets of heat dissipation fins.

[0012] (III) Beneficial Effects

[0013] Compared with the prior art, the beneficial effects of this utility model are as follows:

[0014] 1. The high-efficiency condenser uses a water-cooling system. By setting up a drive motor and drive shaft to drive the rotating fan blades and rotating disc, the rotating fan blades rotate to dissipate heat from the annular heat sink, accelerate airflow, and, together with the heat dissipation fins, can quickly dissipate the heat carried by the cooling water in the spiral water channel to the outside, effectively reduce the cooling water temperature, improve the cooling effect on the condenser, and enhance the convenience of using the condenser.

[0015] 2. The synchronous condenser with this cooling efficiency uses a water cooling system. By setting a heat-conducting probe and a cooling fan on the left side of the cooling water tank, when the water temperature in the cooling water tank rises, the heat-conducting probe senses the temperature change and starts the cooling fan to further reduce the water temperature in the tank, ensuring that the cooling water is always at a low temperature and continuously providing a good cooling effect for the synchronous condenser. Combined with the synergistic effect of the cooling device and the cooling water tank, a highly efficient cooling circulation system is formed, which significantly improves the cooling efficiency of the synchronous condenser. Attached Figure Description

[0016] Figure 1 This is a schematic diagram of the structure of this utility model;

[0017] Figure 2 This is a schematic diagram of the vertical cross-section of the present invention;

[0018] Figure 3 This is a schematic diagram of the cooling and temperature reduction device of this utility model;

[0019] In the diagram: 1. Camera housing; 2. Sealing cover; 3. Spiral water channel; 4. Cooling device; 401. Annular heat sink; 402. Heat sink fins; 403. Drive motor; 404. Drive shaft; 405. Rotating fan blades; 406. Circular bracket; 407. Rotating circular plate; 408. Rotating fan blades; 409. L-shaped positioning plate; 5. Cooling water tank; 6. Cooling water pump; 7. Suction pipe; 8. Discharge pipe; 9. Return pipe; 10. Thermal probe; 11. Cooling fan. Detailed Implementation

[0020] The technical solution of this patent will be further described in detail below with reference to specific embodiments.

[0021] like Figure 1-3 As shown, this utility model provides a technical solution: a water-cooled system for a high-efficiency camera condenser, including a camera condenser housing 1. A sealing cover 2 is bolted to the left side of the camera condenser housing 1. The sealing cover 2 is made of high-temperature resistant and corrosion-resistant stainless steel. A spiral water channel 3 is installed inside the sealing cover, tightly abutting against the inner wall of the camera condenser housing 1. The spiral water channel 3 is made of copper pipe with good thermal conductivity, which can efficiently transfer the heat inside the camera condenser housing to the internal cooling water. A cooling device 4 is provided on the left side of the spiral water channel 3. A cooling water tank 5 is fixedly installed on the left side of the camera condenser housing 1 by a bracket. A cooling water pump 6 is bolted to the upper surface of the cooling water tank 5. The input end of the cooling water pump 6 is connected to a suction pipe 7 that runs through the inside of the cooling water tank 5. A filter screen is installed at the end of the suction pipe 7 to prevent impurities from entering the cooling water pump. The output end of the cooling water pump 6 is connected to an outlet pipe 8. A return pipe 9 is connected to the left side of the cooling water tank 5. A heat conduction probe 10 is fixedly installed on the left side of the cooling water tank 5 by welding. The heat conduction probe 10 is made of a metal material with a high thermal conductivity and can quickly sense changes in the water temperature inside the cooling water tank. A cooling fan 11 is fixedly installed on the upper surface of the heat conduction probe 10 by bolts. The cooling fan 11 is connected to the heat conduction probe 10 through a temperature sensor. When the heat conduction probe detects that the water temperature has reached a certain threshold, the cooling fan is automatically started to assist in heat dissipation.

[0022] The cooling device 4 includes an annular heat sink 401 fixedly installed on the left side of the spiral water channel 3. The annular heat sink 401 is made of aluminum alloy. Heat sink fins 402 are fixedly installed on the outer surface of the annular heat sink 401. A drive motor 403 is fixedly installed on the left side of the sealing cover 2 by bolts. A drive shaft 404 is fixedly installed on the output end of the drive motor 403 by a coupling. A rotating fan blade 405 is fixedly installed on the outer surface of the drive shaft 404 by a key connection. A circular bracket 406 connected to the inner wall of the annular heat sink 401 is rotatably installed on the outer surface of the drive shaft 404 to support the drive shaft 404. A rotating circular plate 407 is fixedly installed on the left end of the drive shaft 404 by bolts. A rotating fan blade 408 is fixedly installed on the inner side of the rotating circular plate 407 by bolts. An L-shaped positioning plate 409 connected to the left side of the sealing cover 2 is slidably provided on the left side of the rotating circular plate 407.

[0023] Specifically, such as Figure 1 and Figure 2 As shown, the tops of both the outlet pipe 8 and the return pipe 9 are connected to the right side of the annular heat sink 401 via flanges, ensuring the sealing and stability of the water circuit connection.

[0024] Specifically, such as Figure 3 As shown, an annular sliding groove is provided on the left side of the rotating circular plate 407, and a sliding column is fixedly installed on the inner side of the L-shaped positioning plate 409. The annular sliding groove and the sliding column are slidably connected, so that the rotating circular plate 407 can remain stable when rotating without affecting its rotation. There are twenty sets of heat dissipation fins 402. Rectangular ventilation holes are provided on the outer side of each of the twenty sets of heat dissipation fins 402 to increase the air circulation area and improve the heat dissipation efficiency.

[0025] The working principle of this utility model is as follows:

[0026] S1. When the camera adjuster is working, it generates heat, which is transferred to the camera adjuster housing 1, and then to the cooling water in the spiral water channel 3 that abuts against the inner wall of the housing, causing the cooling water temperature to rise. Subsequently, the cooling water pump 6 starts, and the cooling water pump 6 draws the cooling water from the cooling water tank 5 through the suction pipe 7 and delivers it to the spiral water channel 3 through the outlet pipe 8. The hot water that has absorbed heat enters the annular heat dissipation cylinder 401.

[0027] S2. Simultaneously start the drive motor 403. The output end of the drive motor 403 drives the drive shaft 404 to rotate. The drive shaft 404 drives the rotating fan blades 405, the rotating circular plate 407, and the rotating fan blades 408 to rotate, accelerating the airflow. When the air flows through the annular heat sink 401 and the heat sink fins 402, it dissipates the heat to the outside. The cooled water flows back to the cooling water tank 5 through the return water pipe 9.

[0028] S3. When the heat conduction probe 10 detects that the water temperature in the cooling water tank 5 has risen to a certain level, the cooling fan 11 is started to further reduce the water temperature in the tank. This cycle is repeated to achieve continuous cooling of the switching camera.

[0029] In summary, the water cooling system of this efficient condenser uses a drive motor 403 and a drive shaft 404 to drive the rotating fan blades 405, rotating disc 407, and rotating fan blades 408 to perform heat dissipation and cooling operations on the annular heat sink 401. This accelerates airflow, and with the help of the heat dissipation fins 402, it can quickly dissipate the heat carried by the cooling water in the spiral water channel 3 to the outside, effectively reducing the cooling water temperature, improving the cooling effect on the condenser, and enhancing the convenience of using the condenser.

[0030] The efficient cooling system for the synchronous condenser uses a water cooling system. By setting a heat-conducting probe 10 and a cooling fan 11 on the left side of the cooling water tank 5, when the water temperature in the cooling water tank rises, the heat-conducting probe 10 senses the temperature change and starts the cooling fan to further reduce the water temperature in the tank, ensuring that the cooling water is always at a low temperature and continuously providing a good cooling effect for the synchronous condenser. Combined with the synergistic effect of the cooling device 4 and the cooling water tank 5, a highly efficient cooling cycle system is formed, which significantly improves the cooling efficiency of the synchronous condenser.

[0031] In the description of this utility model, it should be noted that, unless otherwise explicitly specified and limited, the terms "installation," "connection," and "joining" should be interpreted broadly. For example, they can refer to a fixed connection, a detachable connection, or an integral connection; they can refer to a mechanical connection or an electrical connection; they can refer to a direct connection or an indirect connection through an intermediate medium; and they can refer to the internal connection of two components. Those skilled in the art can understand the specific meaning of the above terms in this utility model based on the specific circumstances.

[0032] The preferred embodiments of this patent have been described in detail above. However, this patent is not limited to the above embodiments. Within the scope of knowledge possessed by those skilled in the art, various changes can be made without departing from the spirit of this patent.

Claims

1. A water-cooled system for a high-efficiency camera condenser, comprising a camera condenser housing (1), wherein a sealing cover (2) is provided on the left side of the camera condenser housing (1), and a spiral water channel (3) is provided inside the sealing cover (2) to abut against the inner wall of the camera condenser housing (1), characterized in that: A cooling device (4) is provided on the left side of the spiral water channel (3), a cooling water tank (5) is provided on the left side of the camera housing (1), a cooling water pump (6) is fixedly installed on the upper surface of the cooling water tank (5), a water suction pipe (7) is connected to the input end of the cooling water pump (6) and passes through the inside of the cooling water tank (5), a water outlet pipe (8) is connected to the output end of the cooling water pump (6), and a return water pipe (9) is connected to the left side of the cooling water tank (5).

2. The water-cooled system for a switching camera with high cooling efficiency according to claim 1, characterized in that: A heat-conducting probe (10) is fixedly installed on the left side of the cooling water tank (5), and a cooling fan (11) is fixedly installed on the upper surface of the heat-conducting probe (10).

3. The water-cooled system for a switching camera with high cooling efficiency according to claim 1, characterized in that: The cooling device (4) includes an annular heat sink (401) fixedly installed on the left side of the spiral water channel (3). Heat sink fins (402) are fixedly installed on the outer surface of the annular heat sink (401). A drive motor (403) is fixedly installed on the left side of the sealing cover (2). A drive shaft (404) is fixedly installed at the output end of the drive motor (403). A rotating fan blade (405) is fixedly installed on the outer surface of the drive shaft (404). A circular bracket (406) connected to the inner wall of the annular heat sink (401) is fixedly installed on the outer surface of the drive shaft (404). A rotating circular plate (407) is fixedly installed at the left end of the drive shaft (404). A rotating fan blade (408) is fixedly installed on the inner side of the rotating circular plate (407). An L-shaped positioning plate (409) connected to the left side of the sealing cover (2) is slidably provided on the left side of the rotating circular plate (407).

4. The water-cooled system for a switching camera with high cooling efficiency according to claim 1, characterized in that: The tops of the outlet pipe (8) and return pipe (9) are connected to the right side of the annular heat sink (401).

5. A water-cooled system for a switching camera with high cooling efficiency according to claim 3, characterized in that: The left side of the rotating circular plate (407) is provided with an annular sliding groove, and a sliding column is fixedly installed on the inner side of the L-shaped positioning plate (409). The annular sliding groove and the sliding column are slidably connected.

6. A water-cooled system for a switching camera with high cooling efficiency according to claim 3, characterized in that: The number of heat dissipation fins (402) is twenty sets, and rectangular ventilation holes are opened on the outer side of each of the twenty sets of heat dissipation fins (402).

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