CN217546613U - Frame cooling system and multimode imaging device - Google Patents

Abstract

The utility model relates to a frame cooling system and multimode imaging device, wherein frame cooling system includes first frame, second frame, cooling unit and circulation pipeline, has seted up first runner in the first frame, has seted up the second runner in the second frame, and the cooling unit can communicate through circulation pipeline and first frame and second frame, and the cooling unit can be with leading-in first runner of coolant liquid and second runner to dispel the heat to first frame and second frame. The utility model discloses can carry out simultaneously or dispel the heat in turn to first frame and second frame with coolant liquid heat exchange's mode to this radiating efficiency who improves this frame cooling system reduces the heat dissipation cost, the noise of the multi-mode imaging device during operation that has this frame cooling system of having used has also been reduced simultaneously, improve user experience, foreign matters such as reduction dust get into to the inside probability of this frame cooling system, and then make this frame cooling system can be applicable to high-end multi-mode imaging device.

Description

Frame cooling system and multimode imaging device

Technical Field

The utility model relates to an image equipment correlation technique field especially relates to a frame cooling system and multimode imaging device.

Background

A multi-modality imaging device, in particular to a novel imaging device which organically combines imaging devices such as PET (Positive Emission Computed Tomography, short), CT (Computed Tomography, short) and MR (Magnetic Resonance, short) together.

At present, the existing cooling scheme for the whole multi-modal imaging device generally selects air cooling to match with an air cooling compressor for refrigeration, or adopts a water cooling mode to independently realize the heat dissipation of one of the imaging devices of the multi-modal imaging device. The requirement of an internal detector module in high-end equipment on the ambient temperature is relatively high, so that the requirement that the ambient temperature is below a few degrees cannot be realized by adopting a conventional air-cooling heat dissipation mode, namely, the existing heat dissipation mode applied to multi-mode imaging equipment cannot meet the requirement of modern medicine on high image quality accuracy.

SUMMERY OF THE UTILITY MODEL

In view of the above, it is desirable to provide a rack cooling system and a multi-modality imaging apparatus for solving the above problems.

A rack cooling system comprises a first rack and a second rack, wherein the second rack is connected with the first rack;

the cooling system is characterized by further comprising a cooling unit and a circulating pipeline, wherein a first runner is formed in the first rack, a second runner is formed in the second rack, the cooling unit can be communicated with the first rack and the second rack through the circulating pipeline, and cooling liquid can be guided into the first runner and the second runner by the cooling unit so as to dissipate heat of the first rack and the second rack.

In this application, through the above-mentioned cooling unit, the structure setting of first runner and second runner, make this frame cooling system be applied to multimode imaging equipment and during operation, can carry out simultaneously or the heat dissipation to first frame and second frame with coolant liquid heat exchange's mode, with this radiating efficiency who improves this frame cooling system, reduce the heat dissipation cost, the noise of the multimode imaging equipment during operation that has this frame cooling system of using has also been reduced simultaneously, improve user experience, reduce the probability that foreign matters such as dust enter into this frame cooling system inside, and then make this frame cooling system can be applicable to high-end multimode imaging equipment.

In one embodiment, the first flow passage and the second flow passage are connected in series to the cooling unit.

It can be understood that the first flow passage and the second flow passage are connected in series to the circulation pipeline, so as to implement an embodiment of the heat dissipation of the first rack and the second rack.

In one embodiment, the circulation pipeline includes a first liquid outlet pipe, a flow dividing pipe and a first return pipe, the liquid inlet end of the first flow channel is communicated with the first liquid outlet pipe, the liquid outlet end of the first flow channel is respectively communicated with the liquid inlet end of the second flow channel and the first return pipe through the flow dividing pipe, and the liquid outlet end of the second flow channel is communicated with the first return pipe.

It can be understood that, by the structural arrangement of the first outlet pipe, the flow dividing pipe and the first return pipe, an embodiment in which the first flow passage and the second flow passage are communicated with the circulation pipeline is realized.

In one embodiment, the number of the shunt tubes is at least two, at least one shunt tube is communicated with the first flow channel and the second flow channel, and the other shunt tube is communicated with the first return tube in parallel with the liquid outlet end of the second flow channel.

It can be understood that the number of the shunt tubes is set to be at least two, so that the number of the shunt tubes is specifically set to meet the use requirement that the cooling liquid passes through the first flow channel and the second flow channel in sequence when the first flow channel and the second flow channel are connected with the circulating pipeline in series.

In one embodiment, the first flow passage and the second flow passage are communicated with the cooling unit in a parallel manner.

It is understood that the first flow passage and the second flow passage are communicated with the cooling unit in parallel, so as to implement another embodiment that the first flow passage and the second flow passage are communicated with the circulation pipeline.

In one embodiment, the circulation pipeline includes a second liquid outlet pipe and a second return pipe, the liquid inlet end of the first flow channel and the liquid inlet end of the second flow channel are connected in parallel to the second liquid outlet pipe, and the liquid outlet end of the first flow channel and the liquid outlet end of the second flow channel are connected in parallel to the second return pipe.

It can be understood that, by the structural arrangement of the second liquid outlet pipe and the second return pipe, an embodiment of the circulation pipeline when the first rack and the second rack are connected in parallel is realized.

In one embodiment, the circulation pipeline comprises a first liquid outlet pipe, a second liquid outlet pipe, a first backflow pipe and a second backflow pipe, the first flow passage is communicated with the first liquid outlet pipe and the first backflow pipe, and the second flow passage is communicated with the second liquid outlet pipe and the second backflow pipe.

It can be understood that another embodiment of the parallel connection of the first flow passage and the second flow passage with the circulation pipeline is realized by the structural arrangement of the first liquid outlet pipe, the second liquid outlet pipe, the first return pipe and the second return pipe.

In one embodiment, the first flow channel includes a plurality of first branch flow channels, and the plurality of first branch flow channels are arranged in parallel in the first rack.

It can be understood that through the structural arrangement of the multi-path first branch flow channel, the structural arrangement of the first flow channel in the first rack is specifically realized, so that each path of first branch flow channel can respectively carry out water-cooling heat dissipation on one detector module on the first rack, and the use requirement of the water-cooling heat dissipation of the first rack is met.

In one embodiment, the second flow channel includes a plurality of second branch flow channels, and the plurality of second branch flow channels are arranged in parallel in the second rack.

It can be understood that through the structural arrangement of the multiple second branch runners, the structural arrangement of the second runners in the second rack is specifically realized, so that each second branch runner can perform water-cooling heat dissipation on at least one detector module on the second rack respectively, and the use requirement of the water-cooling heat dissipation of the second rack is met.

The application also claims a multi-modality imaging device, which comprises a first rack, a PET device body, a second rack, a CT device body or an MR device body, and a cooling unit, wherein the PET device body is mounted on the first rack, and the CT device body or the MR device body is mounted on the second rack; the PET equipment main body is arranged on the first rack, the CT equipment main body or the MR equipment main body is arranged on the second rack, a first flow channel is formed in the first rack, a second flow channel is formed in the second rack, the cooling unit can be communicated with the first rack and the second rack through a circulating pipeline, cooling liquid can be guided into the first flow channel and the second flow channel through the cooling unit, and therefore the PET equipment main body is cooled through the first rack, and the CT equipment main body or the MR equipment main body is cooled through the second rack.

Because of above-mentioned technical scheme's application, compared with the prior art, the utility model have the following advantage:

the utility model discloses a frame cooling system and multimode imaging device, carry out simultaneously or heat dissipation in turn to first frame and second frame with coolant liquid heat exchange's mode, improve this frame cooling system's radiating efficiency with this, reduce the heat dissipation cost, the noise of the multimode imaging device during operation that has this frame cooling system of application has also been reduced simultaneously, improve user experience, reduce foreign matters such as dust and get into to the inside probability of this frame cooling system, and then make this frame cooling system can be applicable to high-end multimode imaging device.

Drawings

Fig. 1 is a schematic structural diagram of a rack heat dissipation system according to an embodiment of the present application, in which a first rack and a second rack are connected in series to a cooling unit;

fig. 2 is a schematic structural diagram of a rack heat dissipation system according to an embodiment of the present application, in which a first rack and a second rack are connected to a cooling unit in parallel;

fig. 3 is a schematic structural diagram of a rack heat dissipation system according to an embodiment of the present application, in which a first rack and a second rack are respectively connected to a cooling unit;

FIG. 4 is a schematic view of a first frame of the present application;

FIG. 5 is a schematic view of a second frame of the present application;

10, a first frame; 11. a first flow passage; 111. a first branch flow channel; 20. a second frame; 21. a second flow passage; 211. a second branch flow channel; 30. a cooling unit; 40. a circulation line; 401. a liquid outlet pipe; 402. a second liquid outlet pipe; 403. a reflux pipe; 404. a second reflux pipe; 41. a first liquid outlet pipe; 42. a shunt tube; 43. a first return pipe; 410. a second liquid outlet pipe; 420. a second return pipe.

Detailed Description

The technical solutions of the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings, and obviously, the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work all belong to the protection scope of the present invention.

It will be understood that when an element is referred to as being "on" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "disposed on" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "secured to" another element, it can be directly secured to the other element or intervening elements may also be present.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used in the description of the invention herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. As used herein, the term "and/or" includes any and all combinations of one or more of the associated listed items.

The multi-modality imaging apparatus claimed in the present application includes a first gantry 10, a PET apparatus body (not shown), a second gantry 20, a CT apparatus body or an MR apparatus body (not shown), and a cooling unit 30, the PET apparatus body is mounted on the first gantry 10, and the CT apparatus body or the MR apparatus body is mounted on the second gantry 20.

The cooling unit 30 can dissipate heat from the PET apparatus main body by the first gantry 10 and from the CT apparatus main body or the MR apparatus main body by the second gantry 20.

Referring to fig. 1 to 5, a rack heat dissipation system according to an embodiment of the present invention includes a first rack 10, a second rack 20, a cooling unit 30, and a circulation pipeline 40.

The first frame 10 is connected with the second frame 20, and particularly, the first frame 10 and the second frame 20 can be connected into an integrated structure, so that the use requirement of the frame cooling system applied to the multi-mode imaging device is met. It should be noted that the first rack 10 is a PET rack, and specifically, a PET device main body can be mounted on the PET rack; the second rack 20 is a CT rack, and specifically, a CT device main body can be mounted on the CT rack; alternatively, the first gantry 10 may be a PET gantry, and specifically, a PET device body may be mounted on the PET gantry, and the second gantry 20 may be a MR gantry, and specifically, a MR device body may be mounted on the MR gantry, which will not be described herein.

The first frame 10 is provided with a first flow passage 11, the second frame 20 is provided with a second flow passage 21, the cooling unit 30 can be communicated with the first frame 10 and the second frame 20 through a circulation pipeline 40, and the cooling unit 30 can guide cooling liquid into the first flow passage 11 and the second flow passage 21 so as to dissipate heat of the first frame 10 and the second frame 20. When the rack cooling system works, the purpose of cooling the first rack 10 and the second rack 20 is achieved by utilizing the heat exchange between the cooling liquid passing through the first flow channel 11 and the second flow channel 21 and the detector modules (not shown) on the first rack 10 and the second rack 20. That is, the rack heat dissipation system according to the present invention can dissipate heat from the first rack 10 and the second rack 20 by the cooling unit 30 when operating. The cooling unit 30 may be specifically configured as a water cooler, and the cooling liquid is a water cooling liquid, so that the water cooler can guide the water cooling liquid in the circulation line 40, the first flow passage 11 of the first frame 10, and the second flow passage 21 of the second frame 20 when the water cooler is in operation.

It should be noted that, when the rack heat dissipation system works, the heat dissipation effect of the first rack 10 and the second rack 20 can be specifically controlled by controlling the flow rate and the flow speed of the cooling liquid introduced into the first flow passage 11 and the second flow passage 21 according to the use requirement, which will not be described herein.

It can be understood that, the frame cooling system of the present application simultaneously or alternatively dissipates heat to the first frame 10 and the second frame 20 in a cooling liquid heat exchange manner, so as to improve the heat dissipation efficiency of the frame cooling system, reduce the heat dissipation cost, and simultaneously reduce the noise of the multi-mode imaging device to which the frame cooling system is applied during operation, thereby improving the user experience, reducing the probability that foreign matters such as dust enter the interior of the frame cooling system, and further enabling the frame cooling system of the present application to be applicable to more high-end multi-mode imaging devices. It should be noted that the simultaneous heat dissipation means that the first rack 10 and the second rack 20 perform heat dissipation at the same time, and the alternative heat dissipation means that the first rack 10 and the second rack 20 alternate in time.

Because the PET apparatus main body is installed on the first rack 10, and the CT apparatus main body or the MR apparatus main body is installed on the second rack 20, when the temperature of the coolant required by the PET apparatus main body during operation is lower than that of the coolant required by the CT apparatus main body or the MR apparatus main body during operation, for example, when the temperature of the coolant required by the first rack 10 is lower than that of the coolant required by the second rack 20, the rack heat dissipation system of the present application during operation can introduce the coolant into the first flow channel 11 of the first rack 10 to satisfy the low-temperature coolant required by the first rack 10, and realize heat dissipation of the first rack 10, and the coolant passing through the first rack 10 absorbs the heat of the first rack 10, and the temperature rises to some extent, but when the temperature of the coolant still satisfies the temperature requirement of the second rack 20 for the coolant, the coolant introduced from the first rack 10 can be directly introduced into the second flow channel 21 of the second rack 20 to realize heat dissipation of the second rack 20, so that when the rack heat dissipation system operates, a coolant at a certain temperature needs to be provided, and the coolant can satisfy the needs of the second rack 20.

In an embodiment, the first flow channel 11 and the second flow channel 21 are connected to the cooling unit 30 in series, so as to implement an embodiment of heat dissipation of the first rack 10 and the second rack 20.

Accordingly, the circulation pipeline 40 of this embodiment includes a first outlet pipe 41, a dividing pipe 42 and a first return pipe 43, the inlet end of the first flow channel 11 is connected to the first outlet pipe 41, the outlet end of the first flow channel 11 is respectively connected to the inlet end of the second flow channel 21 and the first return pipe 43 through the dividing pipe 42, and the outlet end of the second flow channel 21 is connected to the first return pipe 43.

As can be seen from the above, when the rack heat dissipation system of this embodiment operates, the cooling liquid in the cooling unit 30 flows out from the first liquid outlet pipe 41 and is guided into the first flow channel 11, a part of the cooling liquid guided out after passing through the first rack 10 can be guided into the second flow channel 21 through the shunt pipe 42, the rest part of the cooling liquid flows back into the cooling unit 30 through the first return pipe 43, and the cooling liquid guided out after passing through the second flow channel 21 also flows back into the cooling unit 30 through the first return pipe 43, and forms a circulation of the cooling liquid.

The number of the dividing pipes 42 is at least two, wherein at least one dividing pipe 42 is communicated with the first flow passage 11 and the second flow passage 21, and the liquid outlet ends of at least one dividing pipe 42 and the second flow passage 21 are communicated with the first return pipe 43 in a parallel connection manner, so that the number of the dividing pipes 42 is specifically set, and the use requirements that the cooling liquid sequentially passes through the first flow passage 11 and the second flow passage 21 when the first rack 10 and the second rack 20 are connected in series are met. It should be noted that the number of shunt tubes 42 can be two.

In one embodiment, the first flow channel 11 and the second flow channel 21 are connected to the cooling unit 30 in parallel, so as to implement another embodiment of the heat dissipation of the first rack 10 and the second rack 20.

The circulation pipeline 40 of this embodiment includes a second liquid outlet pipe 410 and a second return pipe 420, wherein the liquid inlet end of the first flow channel 11 and the liquid inlet end of the second flow channel 21 are connected to the second liquid outlet pipe 410 in parallel, and the liquid outlet end of the first flow channel 11 and the liquid outlet end of the second flow channel 21 are connected to the second return pipe 420 in parallel. That is, the first frame 10 and the second frame 20 of this embodiment are connected in parallel to the second outlet pipe 410 and the second return pipe 420.

As can be seen from the above, when the rack heat dissipation system of this embodiment works, the cooling liquid in the cooling unit 30 can be guided into the first flow channel 11 and the second flow channel 21 after being guided out by the second liquid outlet pipe 410, and then the cooling liquid passing through the first rack 10 and the second rack 20 is returned to the cooling unit 30 by the second return pipe 420, so as to realize circulation of the cooling liquid.

It can be understood that when the first flow channel 11 and the second flow channel 21 are connected in parallel, the first flow channel 11 on the first rack 10 and the second flow channel 21 on the second rack 20 are not limited to be connected in parallel to the pipeline led out from the cooling unit 30, and the first flow channel 11 and the second flow channel 21 may be directly connected to the cooling unit 30 respectively.

The circulating pipeline 40 includes a first liquid outlet pipe 401, a second liquid outlet pipe 402, a first backflow pipe 403 and a second backflow pipe 404, the first flow channel 11 is communicated with the cooling unit 30 through the first liquid outlet pipe 401 and the first backflow pipe 403, and the second flow channel 21 is communicated with the cooling unit 30 through the second liquid outlet pipe 402 and the second backflow pipe 404, so that the structural arrangement of the circulating pipeline 40 when the first rack 10 and the second rack 20 are connected in parallel is realized.

In an embodiment, the first flow channel 11 includes a plurality of first branch flow channels 111, and the plurality of first branch flow channels 111 are arranged in parallel in the first rack 10, so as to implement the structural arrangement of the first flow channel 11 in the first rack 10, so that each first branch flow channel 111 can perform water-cooling heat dissipation on at least one detector module on the first rack 10, so as to meet the use requirement of the water-cooling heat dissipation of the first rack 10. It should be noted that the first branch flow channel 111 is specifically disposed in the first rack 10 according to a heat dissipation requirement of the first rack 10, and may correspond to one detector module and also correspond to multiple detector modules at the same time, which is not described herein.

In an embodiment, the second flow channel 21 includes a plurality of second branch flow channels 211, and the plurality of second branch flow channels 211 are arranged in parallel in the second rack 20, so as to implement the structural arrangement of the second flow channel 21 in the second rack 20, so that each second branch flow channel 211 can respectively perform water-cooling heat dissipation on at least one detector module on the second rack 20, so as to meet the use requirement of the water-cooling heat dissipation of the second rack 20. It should be noted that the second branch flow channel 211 is disposed in the second frame 20, and may be specifically configured according to the requirement of heat dissipation of the second frame 20, and may correspond to one detector module, and also correspond to a plurality of detector modules, which is not described herein.

In addition, an air cooling module (not shown) is disposed on the first rack 10 and/or the second rack 20 for cooling the first rack 10 and/or the second rack 20, so that the first rack 10 and/or the second rack 20 can also cool the air to further ensure the usage requirement of cooling the first rack 10 and/or the second rack 20.

Compared with the prior art, the utility model discloses a frame cooling system, through above-mentioned cooling unit 30, the structure setting of first runner 11 and second runner 21, make this frame cooling system be applied to multimode imaging device and during operation, can carry out simultaneously or dispel the heat in turn to first frame 10 and second frame 20 with coolant liquid heat exchange's mode, with this radiating efficiency who improves this frame cooling system, reduce the heat dissipation cost, the noise of the multimode imaging device during operation that has applied this frame cooling system has also been reduced simultaneously, improve user experience, reduce foreign matter such as dust and get into to the inside probability of this frame cooling system, and then make this frame cooling system can be applicable to high-end multimode imaging device.

The features of the above embodiments may be arbitrarily combined, and for the sake of brevity, all possible combinations of the features in the above embodiments are not described, but should be construed as being within the scope of the present specification as long as there is no contradiction between the combinations of the features.

It will be appreciated by those skilled in the art that the above embodiments are only for illustrating the present invention and are not to be used as limitations of the present invention, and that suitable modifications and variations of the above embodiments are within the scope of the present invention as claimed.

Claims (10)

1. A rack cooling system comprises a first rack (10) and a second rack (20), wherein the second rack (20) is connected with the first rack (10);

the cooling system is characterized by further comprising a cooling unit (30) and a circulating pipeline (40), wherein a first flow channel (11) is formed in the first rack (10), a second flow channel (21) is formed in the second rack (20), the cooling unit (30) can be communicated with the first rack (10) and the second rack (20) through the circulating pipeline (40), and cooling liquid can be introduced into the first flow channel (11) and the second flow channel (21) through the cooling unit (30) so as to dissipate heat of the first rack (10) and the second rack (20).

2. The rack cooling system according to claim 1, wherein the first flow channel (11) and the second flow channel (21) are in series communication with the cooling unit (30).

3. The rack cooling system according to claim 2, wherein the circulation pipeline (40) includes a first liquid outlet pipe (41), a shunt pipe (42), and a first liquid return pipe (43), a liquid inlet end of the first flow channel (11) is connected to the first liquid outlet pipe (41), a liquid outlet end of the first flow channel (11) is connected to the liquid inlet end of the second flow channel (21) and the first liquid return pipe (43) through the shunt pipe (42), respectively, and a liquid outlet end of the second flow channel (21) is connected to the first liquid return pipe (43).

4. The rack cooling system according to claim 3, wherein the number of the shunt tubes (42) is at least two, at least one of the shunt tubes (42) is communicated with the first flow passage (11) and the second flow passage (21), and the outlet ends of the shunt tubes (42) and the second flow passage (21) are communicated with the first return tube (43) in parallel.

5. The rack cooling system according to claim 1, wherein the first flow channel (11) and the second flow channel (21) are connected in parallel to the cooling unit (30).

6. The rack cooling system according to claim 5, wherein the circulation pipeline (40) includes a second liquid outlet pipe (410) and a second return pipe (420), a liquid inlet end of the first flow channel (11) and a liquid inlet end of the second flow channel (21) are connected in parallel to the second liquid outlet pipe (410), and a liquid outlet end of the first flow channel (11) and a liquid outlet end of the second flow channel (21) are connected in parallel to the second return pipe (420).

7. The rack heat dissipation system according to claim 5, wherein the circulation pipeline (40) includes a first outlet pipe (401), a second outlet pipe (402), a first return pipe (403), and a second return pipe (404), the first flow channel (11) is communicated with the cooling unit (30) through the first outlet pipe (401) and the first return pipe (403), and the second flow channel (21) is communicated with the cooling unit (30) through the second outlet pipe (402) and the second return pipe (404).

8. The rack heat dissipation system according to claim 1, wherein the first flow channel (11) comprises a plurality of first branch flow channels (111), and the plurality of first branch flow channels (111) are arranged in parallel in the first rack (10).

9. The rack heat dissipation system of claim 1, wherein the second flow channel (21) comprises a plurality of second branch flow channels (211), the plurality of second branch flow channels (211) being arranged in parallel within the second rack (20).

10. A multi-modality imaging apparatus includes a first gantry (10), a PET apparatus body mounted on the first gantry (10), a second gantry (20), a CT apparatus body or an MR apparatus body mounted on the second gantry (20), and a cooling unit (30); the PET equipment is characterized in that a first flow channel (11) is formed in the first rack (10), a second flow channel (21) is formed in the second rack (20), the cooling unit (30) can be communicated with the first rack (10) and the second rack (20) through a circulating pipeline (40), and the cooling unit (30) can guide cooling liquid into the first flow channel (11) and the second flow channel (21) so that the PET equipment main body can be cooled by the first rack (10) and the CT equipment main body or the MR equipment main body can be cooled by the second rack (20).

Images