CN217876573U - One-way circulation type siphon radiator with gas-liquid separation and separation mechanism - Google Patents

Abstract

The utility model provides an one-way circulating has siphon radiator of gas-liquid separation mechanism, including the condenser, the condensate liquid pipeline, the connector, the steam generator, the connecting plate, sealed head and evaporating gas pipeline, wherein: the two ends of one side of the surface of the condenser are symmetrically provided with a condensed liquid pipeline and an evaporated gas pipeline respectively, the condenser is connected with the connector through the condensed liquid pipeline and the evaporated gas pipeline respectively, and the connector is arranged in the middle of one side of the surface of the steam generator. The utility model discloses when using, edgewise about adopting, and the below has the liquid and supplyes the passageway, because gas density is little to can not sink against the current, just can have the gaseous adverse current of effective control refrigerant evaporating, and liquid can see through liquid again and supplyes the refrigerant liquid of passageway supplyes, and its function, the marketing and the application of being convenient for of this two very important functions ability thorough performance of mechanism here.

Description

One-way circulation type siphon radiator with gas-liquid separation and separation mechanism

Technical Field

The utility model relates to a radiator field especially relates to a one-way circulating has siphon radiator of gas-liquid separation mechanism.

Background

The CPU can generate a large amount of heat when working, if the heat is not dissipated in time, the heat is easy to crash, the CPU can be burnt out, and the CPU radiator is used for radiating the CPU. The radiator plays a decisive role in stable operation of the CPU, and it is very important to choose a good radiator when assembling the computer.

In the single-circulation type refrigerant two-phase change siphon heat sink, the evaporator absorbs heat to vaporize the liquid refrigerant, and the vapor will flow freely to the low pressure region, but because it is desired to form internal circulation in the cavity, the vapor region and the liquid reflux region are separated by the pressure difference relationship, and at the same time, the liquid has the function of supplementing the evaporation region to prevent the gas from flowing backwards. Since there are no other related designs in the industry and no other effective designs can be referred to, this mechanism is currently the most effective mechanism for gas-liquid separation.

Therefore, it is necessary to invent a single-direction circulation type siphon radiator with a gas-liquid separation and separation mechanism.

SUMMERY OF THE UTILITY MODEL

In order to solve the technical problem, the utility model provides an one-way circulating has siphon radiator of gas-liquid separation mechanism. The utility model provides a one-way circulating has siphon radiator of gas-liquid separation mechanism, includes the condenser, the condensate liquid pipeline, the connector, steam generator, the connecting plate, sealed head and boil off gas pipeline, wherein: the two ends of one side of the surface of the condenser are symmetrically provided with a condensed liquid pipeline and an evaporated gas pipeline respectively, the condenser is connected with a connector through the condensed liquid pipeline and the evaporated gas pipeline respectively, and the connector is arranged in the middle of one side of the surface of the steam generator; the bottom surface of the steam generator is provided with a connecting plate, and the middle of the other side of the surface of the steam generator is provided with a sealing head.

The condenser comprises a first gas-liquid heat exchange micro-channel, a second gas-liquid heat exchange micro-channel, a backflow channel and an air inlet channel, and the first gas-liquid heat exchange micro-channel and the second gas-liquid heat exchange micro-channel are respectively arranged at symmetrical positions in the condenser; the backflow channel is arranged at one end of the first gas-liquid heat exchange microchannel and one end of the second gas-liquid heat exchange microchannel, and the other end of the first gas-liquid heat exchange microchannel and the other end of the second gas-liquid heat exchange microchannel are provided with an air inlet channel.

The steam generator comprises a protective shell, a first cavity chamber, a second cavity chamber, an air outlet pipe and an air-liquid barrier, wherein the first cavity chamber and the second cavity chamber are symmetrically arranged in the protective shell, and are communicated; the air outlet pipe is arranged between the upper surfaces of the first chamber and the second chamber; the gas-liquid blocker is arranged on one side of the inner part of the surface of the first chamber.

The gas-liquid barrier comprises a barrier plate, an upper edge, a lower edge, a first liquid supplement channel, a second liquid supplement channel, a third liquid supplement channel and a fourth liquid supplement channel, wherein an upper edge and a lower edge are arranged at the positions of one side of the top end surface and one side of the bottom end surface of the barrier plate in a mirror image manner; the positions of the first liquid replenishing channel and the second liquid replenishing channel which are mirror images are arranged on the lower sides of two ends of the surface of the barrier plate; and the third liquid supplementing channel and the fourth liquid supplementing channel penetrate through the lower edge in symmetrical positions and are arranged below two sides of the surface of the barrier plate.

Compared with the prior art, the utility model has the advantages of:

through the setting of gas-liquid separation ware, because this mechanism adopts upper and lower edgewise, and the below has the liquid and supplyes the passageway, and the upper side edgewise is direct to be welded with the evaporimeter upper cover and is sealed, and the below edgewise welds with the evaporimeter base, because gas density is little, and can not sink the adverse current, just can have the adverse current of effective control refrigerant evaporating gas, and liquid can see through liquid and supplyes refrigerant liquid again of liquid supply passageway, and these two very important functions can exert its function thoroughly at this mechanism.

Drawings

Fig. 1 is a schematic view of the overall structure of the present invention.

Fig. 2 is a schematic view of the internal structure of the steam generator of the present invention.

Fig. 3 is a schematic view of the steam generator and the connecting plate of the present invention.

Fig. 4 is a schematic structural view of the gas-liquid separator of the present invention.

In the figure:

the condenser comprises a condenser 1, a first gas-liquid heat exchange micro-channel 11, a second gas-liquid heat exchange micro-channel 12, a return channel 13, an air inlet channel 14, a condensed liquid pipeline 2, a connector 3, a steam generator 4, a protective shell 41, a first chamber 42, a second chamber 43, an air outlet pipe 44, a gas-liquid blocker 45, a blocking plate 451, an upper edge 452, a lower edge 453, a first liquid supplementing channel 454, a second liquid supplementing channel 455, a third liquid supplementing channel 456, a fourth liquid supplementing channel 457, a connecting plate 5, a sealing head 6 and an evaporated gas pipeline 7.

Detailed Description

In order to make the technical solutions of the present invention better understood, the technical solutions in the embodiments of the present invention will be clearly and completely described below, and it is obvious that 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 efforts shall belong to the protection scope of the present invention.

The invention is further described below with reference to the accompanying drawings:

example one

Referring to fig. 1-4, a one-way circulation type siphon radiator with gas-liquid separation blocking mechanism comprises a condenser 1, a condensed liquid pipeline 2, a connector 3, a steam generator 4, a connecting plate 5, a sealing head 6 and an evaporation gas pipeline 7, wherein: a condensed liquid pipeline 2 and an evaporated gas pipeline 7 are respectively arranged at the two symmetrical positions of the two ends of one side of the surface of the condenser 1, the condenser 1 is respectively connected with a connector 3 through the condensed liquid pipeline 2 and the evaporated gas pipeline 7, and the connector 3 is arranged in the middle of one side of the surface of the steam generator 4; the bottom surface of the steam generator 4 is provided with a connecting plate 5, and the middle of the other side of the surface of the steam generator 4 is provided with a sealing head 6; the inside of connector 3 is provided with boil-off gas outlet passage and condensed liquid inlet passage, and the inside boil-off gas outlet passage of connector 3 is connected with the one end of boil-off gas pipeline 7, and the inside condensed liquid inlet passage of this connector 3 is connected with the one end of condensed liquid pipeline 2.

The condenser 1 comprises a first gas-liquid heat exchange microchannel 11, a second gas-liquid heat exchange microchannel 12, a reflux channel 13 and an air inlet channel 14, and the first gas-liquid heat exchange microchannel 11 and the second gas-liquid heat exchange microchannel 12 are respectively arranged at symmetrical positions in the condenser 1; the return channel 13 is arranged at one end of the first gas-liquid heat exchange microchannel 11 and one end of the second gas-liquid heat exchange microchannel 12, and the other end of the first gas-liquid heat exchange microchannel 11 and the other end of the second gas-liquid heat exchange microchannel 12 are provided with an air inlet channel 14; one end of the return channel 13 is connected with one end of the condensed liquid pipeline 2, one end of the gas inlet channel 14 is connected with one end of the evaporated gas pipeline 7, and the first gas-liquid heat exchange micro-channel 11 and the second gas-liquid heat exchange micro-channel 12 are respectively communicated with the return channel 13 and the gas inlet channel 14.

The steam generator 4 comprises a protective shell 41, a first chamber 42, a second chamber 43, an air outlet pipe 44 and an air-liquid barrier 45, wherein the first chamber 42 and the second chamber 43 are symmetrically arranged in the protective shell 41, and the first chamber 42 is communicated with the second chamber 43; the outlet pipe 44 is arranged in the middle of the upper surfaces of the first chamber 42 and the second chamber 43; the gas-liquid blocker 45 is arranged at one side of the surface inside the first chamber 42; the outlet pipe 44 is respectively communicated with the inside of the first chamber 42 and the second chamber 43, and one end of the outlet pipe 44 is connected with the boil-off gas outlet passage inside the connector 3.

The gas-liquid barrier 45 includes a barrier plate 451, an upper rim 452, a lower rim 453, a first liquid supply passage 454, a second liquid supply passage 455, a third liquid supply passage 456, and a fourth liquid supply passage 457, and the upper rim 452 and the lower rim 453 are provided at positions where one side of the top end surface and one side of the bottom end surface of the barrier plate 451 are mirror images; the positions of the first liquid replenishing channel 454 and the second liquid replenishing channel 455 are mirror images and are arranged at the lower sides of two ends of the surface of the barrier plate 451; the liquid replenishing channel three 456 and the liquid replenishing channel four 457 penetrate through the lower edge 453 at symmetrical positions and are arranged below two sides of the surface of the barrier plate 451; the upper edge 452 is welded and sealed with the upper cover of the evaporator, and the lower edge is welded with the base of the evaporator; the first liquid supply channel 454, the second liquid supply channel 455, the third liquid supply channel 456 and the fourth liquid supply channel 457 are respectively connected to a condensed liquid inlet channel inside the connecting head 3.

In the embodiment, when in use, the design mainly uses the heat conduction principle of the refrigerant and the rapid heat transfer property of the liquid, the refrigerant of the internal working fluid absorbs latent heat by phase change to form a temperature difference between the front end and the rear end, thereby achieving the purpose of transmitting a large amount of heat energy; after the heat is absorbed by the heating end of the CPU, the steam generator 4 leads the refrigerant to absorb the heat, and then the refrigerant boils in the steam generator 4 to evaporate nodules and change from liquid state to gas state; the vaporized steam is transferred to the condenser 1 from the steam generator 4 through the evaporation gas pipeline 7 due to the pressure difference relationship caused by the volume enlargement; the vaporized steam passes through the first gas-liquid heat exchange micro-channel 11 and the second gas-liquid heat exchange micro-channel 12; the liquid flows back to the steam generator 4 through the condensate liquid pipe 2, and then through the arrangement of the gas-liquid separator 45, because the gas density is low and the liquid cannot sink and flow reversely, the countercurrent of the refrigerant evaporation gas can be effectively controlled, and the liquid can be supplemented with the refrigerant liquid through the liquid supplementing channel, so that a cycle is completed.

Utilize technical scheme, or technical personnel in the field are in the utility model discloses under technical scheme's the inspiration, design similar technical scheme, and reach above-mentioned technological effect, all fall into the utility model discloses a protection scope.

Claims (4)

1. The utility model provides a one-way circulating has siphon radiator of gas-liquid separation mechanism which characterized in that: including condenser (1), condensate liquid pipeline (2), connector (3), steam generator (4), connecting plate (5), sealing head (6) and boil off gas pipeline (7), wherein: a condensed liquid pipeline (2) and an evaporated gas pipeline (7) are respectively arranged at the two ends of one side of the surface of the condenser (1) in a symmetrical manner, the condenser (1) is respectively connected with a connector (3) through the condensed liquid pipeline (2) and the evaporated gas pipeline (7), and the connector (3) is arranged in the middle of one side of the surface of the steam generator (4); the bottom surface of the steam generator (4) is provided with a connecting plate (5), and the middle of the other side of the surface of the steam generator (4) is provided with a sealing head (6).

2. A siphon radiator with gas-liquid separation and separation mechanism in one-way circulation type as claimed in claim 1, wherein: the condenser (1) comprises a first gas-liquid heat exchange micro-channel (11), a second gas-liquid heat exchange micro-channel (12), a backflow channel (13) and an air inlet channel (14), and the first gas-liquid heat exchange micro-channel (11) and the second gas-liquid heat exchange micro-channel (12) are respectively arranged at symmetrical positions in the condenser (1); the backflow channel (13) is arranged at one end of the first gas-liquid heat exchange microchannel (11) and the second gas-liquid heat exchange microchannel (12), and the other end of the first gas-liquid heat exchange microchannel (11) and the second gas-liquid heat exchange microchannel (12) is provided with an air inlet channel (14).

3. A siphon radiator with gas-liquid separation and separation mechanism in one-way circulation type as claimed in claim 1, wherein: the steam generator (4) comprises a protective shell (41), a first chamber (42), a second chamber (43), an air outlet pipe (44) and an air-liquid barrier (45), wherein the first chamber (42) and the second chamber (43) are symmetrically arranged in the protective shell (41), and the first chamber (42) is communicated with the second chamber (43); the air outlet pipe (44) is arranged between the upper surfaces of the first chamber (42) and the second chamber (43); the gas-liquid blocker (45) is arranged on one side of the surface inside the first chamber (42).

4. A siphon radiator with gas-liquid separation and isolation mechanism of unidirectional circulation type according to claim 3, characterized in that: the gas-liquid blocker (45) comprises a blocking plate (451), an upper edge (452), a lower edge (453), a first liquid supplementing channel (454), a second liquid supplementing channel (455), a third liquid supplementing channel (456) and a fourth liquid supplementing channel (457), wherein the upper edge (452) and the lower edge (453) are arranged at positions, which are mirror images, of one side of the top end face and one side of the bottom end face of the blocking plate (451); the positions of the first liquid replenishing channel (454) and the second liquid replenishing channel (455) which are mirror images are formed on the lower sides of two ends of the surface of the barrier plate (451); the liquid supplementing channel III (456) and the liquid supplementing channel IV (457) penetrate through the lower edge (453) at symmetrical positions and are arranged below two sides of the surface of the barrier plate (451).

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