CN219068441U - Water-cooled ray source device - Google Patents

Abstract

The application belongs to the technical field of X rays, a water-cooling ray source device is disclosed, including the ray source casing, set up in the X ray source subassembly in the ray source casing, the outside of ray source casing is attached with the water-cooling board, the cooling water circulation passageway has been seted up in the water-cooling board, a side of water-cooling board is provided with into water nozzle stub and goes out water nozzle stub, it is connected with cooling water source to advance water nozzle stub and go out water nozzle stub. The water cooling plate is arranged on the outer side of the radiation source shell and is used for transferring heat in the radiation source shell and on the outer shell to the water cooling plate, and cooling water circularly flows in the water cooling plate to take away the heat on the water cooling plate, so that the heat of the radiation source shell is taken away, the radiation source shell is cooled and radiated, the oil temperature in the radiation source shell and the temperature of the shell can be greatly reduced, and the radiating efficiency is improved.

Description

Water-cooled ray source device

Technical Field

The utility model relates to the technical field of X rays, in particular to a water-cooling ray source device.

Background

The X-ray source is a core component of X-ray imaging equipment, and whether the X-ray source can safely and stably work has great influence on the imaging function and the imaging quality, and the working process of an X-ray source component can generate heat which needs to be timely dissipated to ensure that the X-ray source can work normally.

The main cooling technology of the current X-ray source is to adopt an air cooling technology, namely, a cooling fan is arranged. The X-ray source assembly is cooled by a fan. But because the heat dissipation power of the fan is lower, the effect of heating during the operation of the X-ray source assembly is not very good, and the heat of the part of the heat cannot be taken away by the fan and can influence the normal operation of the X-ray source and damage the X-ray source, so that the service life of the X-ray source is reduced.

Disclosure of Invention

In order to solve the above problems, the present utility model provides a water-cooled radiation source device.

The technical aim of the utility model is realized by the following technical scheme: the utility model provides a water-cooling ray source device, includes the ray source casing, set up in the X ray source subassembly in the ray source casing, the outside of ray source casing is attached with the water-cooling board, set up cooling water circulation passageway in the water-cooling board, water-cooling board one side is provided with into water nozzle stub and goes out the water nozzle stub, it is connected with cooling water source to advance water nozzle stub and go out the water nozzle stub.

Through adopting above-mentioned technical scheme, set up the water-cooling board in the ray source casing outside for with the heat transfer on the ray source casing and the shell to the water-cooling board on, rethread cooling water is at the inside circulation flow of water-cooling board take away the heat on the water-cooling board, thereby take away the heat of ray source casing, cool off the heat dissipation to the ray source casing, but the oil temperature in the greatly reduced ray source casing and the temperature of casing improve radiating efficiency.

Further, the water cooling plate is provided with 3 and interval arrangement at least, the inlet pipe of water cooling plate passes through inlet tube connection, and the outlet pipe of water cooling plate passes through outlet pipe connection, inlet tube and outlet pipe's one end is sealed, the other end is connected with the cooling water source.

By adopting the technical scheme, at least 3 water cooling plates are arranged, so that each water cooling plate can be completely attached to the surface of the radiation source shell, and the heat dissipation efficiency is greatly improved.

Further, a fixing plate is arranged on one side surface of the water-cooling plate back-away radiation source shell, the fixing plate is arranged along the arrangement direction of the water-cooling plates and spans across the two water-cooling plates, and the fixing plate is positioned at the gap between the two water-cooling plates and fixedly connected with the radiation source shell through bolts.

Through adopting above-mentioned technical scheme, set up the fixed plate and be used for fixing the water-cooling plate at the ray source casing, improve the stability of water-cooling plate and the fine level of ray source casing, avoid the water-cooling plate to drop and influence radiating efficiency.

Further, the fixed plate is provided with 4 at least, and every two water-cooling plates that are arranged adjacently are provided with 2.

Through adopting above-mentioned technical scheme, every two water-cooling boards that arrange adjacently set up 2 fixed plates, stability is better.

Further, a water cooling cover is arranged on the periphery of the water cooling plate, the water cooling cover is in sealing connection with the ray source shell, a water inlet and a water outlet are arranged on the side wall of the water cooling cover, the water inlet pipe is connected with the water inlet, the water outlet pipe is connected with the water outlet, and the water inlet and the water outlet are connected with a cooling water source through external pipelines.

By adopting the technical scheme, the water cooling cover is arranged on the periphery of the water cooling plate, so that the temperature difference of two sides of the water cooling plate can be stabilized, condensed water is prevented from being generated on the outer side of the water cooling plate, and water accumulation on the radiation source shell is avoided.

Furthermore, the water inlet and the water outlet are both provided with pagoda joints.

Through adopting above-mentioned technical scheme, all set up the pagoda and connect in water inlet and delivery port department, the cooling water piping of the cooling water source of being convenient for is connected with water inlet and delivery port, adopts the pagoda to connect, and interface department is difficult for droing, and stability is good.

Furthermore, a cooling fan is arranged on one side of the ray source shell.

Through adopting above-mentioned technical scheme, still set up cooling fan in radiation source casing one side, further dispel the heat to the radiation source casing through cooling fan, improve radiating efficiency.

In summary, the utility model has the following beneficial effects: in this application, through set up the water-cooling board in the ray source casing outside for on transferring the water-cooling board with the heat on the ray source casing and the shell, rethread cooling water is at the inside circulation flow of water-cooling board takes away the heat on the water-cooling board, thereby takes away the heat of ray source casing, carries out the cooling heat dissipation to the ray source casing, but the oil temperature in the ray source casing of greatly reduced and the temperature of casing improve radiating efficiency.

Drawings

FIG. 1 is a schematic overall structure of an embodiment of the present utility model;

FIG. 2 is a schematic view of the internal structure of an embodiment of the present utility model for highlighting.

In the figure: 10. a radiation source housing; 20. a water cooling plate; 21. a water inlet short pipe; 22. a short water outlet pipe; 23. a water inlet pipe; 24. a water outlet pipe; 30. a fixing plate; 31. a bolt; 40. a water cooling cover; 41. a water inlet; 42. a water outlet; 43. a pagoda joint; 50. and a cooling fan.

Detailed Description

The technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application; it is apparent that the described embodiments are only a part of the embodiments of the present application, not all of the embodiments, and all other embodiments obtained by a person having ordinary skill in the art without making creative efforts based on the embodiments in the present application are within the scope of protection of the present application.

As shown in fig. 1-2, the embodiment of the application discloses a water-cooling ray source device, including a ray source housing 10, a water-cooling plate 20 is attached to the outside of the ray source housing 10, so as to transfer heat of the ray source housing 10 to the water-cooling plate 20, and then the water-cooling plate 20 is used for cooling the water-cooling plate 20, so that the heat of the ray source housing 10 is indirectly cooled, the oil temperature in the ray source housing 10 and the temperature of the housing can be greatly reduced, and compared with a traditional cooling fan, the heat-dissipating efficiency is greatly improved.

Specifically, a cooling water circulation passage is formed in the water cooling plate 20, and cooling water is distributed in the water cooling plate 20, thereby improving the heat dissipation capacity of the water cooling plate 20 and the radiation source housing 10. A water inlet short pipe 21 and a water outlet short pipe 22 are arranged at one side of the water cooling plate 20, and the water inlet short pipe 21 and the water outlet short pipe 22 are respectively connected with an inlet and an outlet of a cooling water circulation channel in the water cooling plate 20 and are used for guiding and discharging cooling water into the water cooling plate 20. The other ends of the water inlet short pipe 21 and the water outlet short pipe 22 are connected with the outlet and the inlet of the cooling water source.

In particular, since the surface of the source housing 10 is not a complete plane, there are typically protrusions forming a reinforcing structure, and a plane is provided between the protrusions. Therefore, in order to make the water cooling plates 20 better fit with the surface of the radiation source housing 10, at least 3 water cooling plates 20 are provided, and each water cooling plate 20 is arranged at intervals and on a plane between two protrusions. A fixing plate 30 is arranged on one side surface of the water cooling plate 20, which is far away from the radiation source shell 10, the fixing plate 30 is arranged along the arrangement direction of the water cooling plates 20 and spans across the two water cooling plates 20, at least 4 fixing plates 30 are arranged, 2 water cooling plates 20 which are adjacently arranged are arranged every two, and the fixing plate 30 is positioned at the gap between the two water cooling plates 20 and fixedly connected with the radiation source shell 10 through bolts 31. In this embodiment, 3 water cooling plates 20 are preferably provided, and the 3 water cooling plates 20 are arranged along the width direction of the radiation source housing 10 so as to avoid the convex structure on the radiation source housing 10. The total set up 4 fixed plates 30, set up 2 fixed plates 30 between every two water-cooling boards 20, rethread bolt 31 can be with fixed connection together fixed plate 30, water-cooling board 20 and ray source casing 10, connect fastening, be difficult for droing.

The periphery of the water cooling plate 20 is provided with the water cooling cover 40, the water cooling cover 40 is in sealing connection with the ray source shell 10, namely, the water cooling plate 20 is isolated from the outside, and an independent small environment is formed in the water cooling cover 40, so that condensed water can be prevented from being formed outside the water cooling plate 20 due to temperature difference, and the influence of accumulated water on the ray source shell 10 on the normal operation of the ray source assembly caused by the seepage of accumulated water into the ray source shell 10 is avoided.

The side wall of the water cooling cover 40 is provided with a water inlet 41 and a water outlet 42, the water inlet short pipes 21 of each water cooling plate 20 are connected together through a water inlet pipe 23, one end of the water inlet pipe 23 is closed, and the other end of the water inlet pipe is connected with the water inlet 41; the water outlet short pipes 22 of the water cooling plates 20 are connected together through the water outlet pipe 24, one end of the water outlet pipe 24 is closed, and the other end is connected with the water outlet 42. The water inlet 41 and the water outlet 42 are respectively provided with a pagoda joint 43, and the water inlet 41 and the water outlet 42 are connected with an external pipeline of a cooling water source through the pagoda joints 43.

A cooling fan 50 is further provided on one side of the radiation source housing 10, and the radiation source housing 10 is subjected to auxiliary heat radiation by the cooling fan 50, thereby further improving the heat radiation efficiency.

The use principle of the water-cooling ray source device in the embodiment is as follows: when the radiation source assembly works, the pagoda joint 43 on the side wall water inlet 41 and the water outlet 42 of the water cooling cover 40 is respectively connected with an external pipeline of a cooling water source, cooling water flows into the water inlet pipe 23 from the water inlet 41, then flows into the cooling water circulation channels of the water cooling plates 20 through the water inlet short pipes 21 of the water cooling plates 20, flows out of the water outlet short pipes 22 into the water outlet pipe 24 after circulation is completed in the cooling water circulation channels of the water cooling plates 20, and then flows back into the cooling water source through the water outlet 42 to form circulation. The cooling water takes away heat on the radiation source housing 10 to radiate the radiation source housing 10 when flowing through the water cooling plate 20.

The above description is only a preferred embodiment of the present utility model, and the protection scope of the present utility model is not limited to the above examples, and all technical solutions belonging to the concept of the present utility model belong to the protection scope of the present utility model. It should be noted that modifications and adaptations to the present utility model may occur to one skilled in the art without departing from the principles of the present utility model and are intended to be within the scope of the present utility model.

Claims (6)

1. A water-cooled radiation source device, characterized by: including ray source casing (10), set up in X ray source subassembly in ray source casing (10), the outside of ray source casing (10) is attached and is equipped with water-cooling board (20), cooling water circulation passageway has been seted up in water-cooling board (20), water-cooling board (20) one side is provided with into water nozzle stub (21) and play water nozzle stub (22), water-cooling board (20) are provided with 3 and interval arrangement at least, water nozzle stub (21) of water-cooling board (20) are connected through inlet tube (23), and water nozzle stub (22) of water-cooling board (20) are connected through outlet pipe (24), one end of inlet tube (23) and outlet pipe (24) is sealed, the other end is connected with the cooling water source.

2. A water cooled radiation source apparatus as claimed in claim 1, wherein: the radiation source is characterized in that a fixing plate (30) is arranged on one side surface of the water cooling plate (20) deviating from the radiation source shell (10), the fixing plate (30) is arranged along the arrangement direction of the water cooling plates (20) and spans across the two water cooling plates (20), and the fixing plate (30) is positioned at the gap between the two water cooling plates (20) and fixedly connected with the radiation source shell (10) through bolts (31).

3. A water cooled radiation source apparatus as claimed in claim 2, wherein: at least 4 fixing plates (30) are arranged, and 2 water cooling plates (20) are arranged every two adjacent fixing plates.

4. A water cooled radiation source device according to claim 3, wherein: the solar radiation source is characterized in that a water cooling cover (40) is arranged on the periphery of the water cooling plate (20), the water cooling cover (40) is in sealing connection with the radiation source shell (10), a water inlet (41) and a water outlet (42) are formed in the side wall of the water cooling cover (40), the water inlet pipe (23) is connected with the water inlet (41), the water outlet pipe (24) is connected with the water outlet (42), and the water inlet (41) and the water outlet (42) are connected with a cooling water source through external pipelines.

5. The water-cooled radiation source device of claim 4, wherein: and pagoda connectors (43) are arranged at the water inlet (41) and the water outlet (42).

6. A water cooled radiation source apparatus as claimed in claim 1, wherein: a cooling fan (50) is further arranged on one side of the radiation source shell (10).

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