CN208459759U - Liquid cooling radiator - Google Patents

Abstract

The utility model provides a kind of liquid cooling radiator, comprising: shell has top plate and bottom plate, foreboard, back plate and two opposite side plates and constitutes accommodating space.The top plate that an at least water inlet pipe is respectively arranged at shell with an at least outlet pipe is outer and is connected to accommodating space.Multiple groups radiating fin is configured in accommodating space and is spaced apart from each other；And partition is configured in accommodating space, and partition between multiple groups radiating fin to constitute at least two circulation roads.At least the axial direction of an outlet pipe and the axial direction of an at least water inlet pipe have the angle between 70 degree to 110 degree, partition misplaces in an at least water inlet pipe, when coolant liquid is from when at least a water inlet pipe enters shell, coolant liquid separately flows at least two circulation roads and by corresponding radiating fin, and leaves shell by an at least outlet pipe.The liquid cooling radiator of the utility model can promote the heat transfer property energy between coolant liquid and radiating fin.

Description

Liquid cooling radiator

Technical field

The utility model relates to a kind of radiators, and in particular to a kind of liquid cooling applied to solid state light emitter projector Formula radiator.

Background technique

Traditional projector mostly uses light source of the high-pressure sodium lamp as projection when, recently as semiconductor fabrication into Step, has been developed using light source made by the semiconductor subassemblies such as light emitting diode or laser.Because made by semiconductor subassembly Light source have the advantages that small in size, light-source brightness is high.However, small in size then have semiconductor subassembly heat generation density is higher to lack Point, therefore requirement of the semiconductor subassembly for heat radiation function is higher.

Now, it uses water-cooling radiating module to be attached at heat source to radiate, cooling water is made to flow into radiating module to draw Waste heat, and waste heat scatters and disappears in outside air through the modes such as conduction and convection current.However, existing water-cooling radiating module majority is adopted The radiating fin stamping to sheet metal, cooling water enter radiating module to contact radiating fin, and the water of cooling water Temperature will rise with the increase of flow distance, since the thermal conduction effect of sheet metal is bad, when flow of cooling water to fin When rear end, cooling water has warmed up can be greatly reduced with the heat transfer property of radiating fin.This will cause the partial region of heat source can not It effectively radiates, and then influences the running of semiconductor light source.

" background technique " paragraph is used only to help to understand the content of the present invention, therefore is taken off in " background technique " paragraph The content of dew may include some known technologies without constituting road known to those skilled in the art.In " background technique " paragraph institute The content of exposure does not represent the content or the utility model one or more embodiment problem to be solved, practical at this It has been readily known to those persons skilled in the art or has recognized before novel application.

Utility model content

The utility model provides a kind of liquid cooling radiator, can promote the heat transfer property energy between coolant liquid and radiating fin.

A kind of liquid cooling radiator of the utility model, comprising: shell has top plate and bottom plate, foreboard, back plate and two Opposite side plate, and top plate and bottom plate, foreboard, back plate and both side plate constitute accommodating space.An at least water inlet pipe, is configured at shell The top plate of body is outer and is connected to accommodating space.An at least outlet pipe is configured at outside the foreboard of shell and is connected to accommodating space.Multiple groups dissipate Hot fin is configured in accommodating space and is spaced apart from each other.Partition is configured in accommodating space, and partition is located at multiple groups heat radiating fin With in being constituted at least two circulation roads in accommodating space between piece.Wherein, at least axial direction of an outlet pipe and an at least water inlet pipe The axial angle having between 70 degree to 110 degree, partition misplace in an at least water inlet pipe.

A kind of liquid cooling radiator of the utility model, comprising: shell has top plate and bottom plate, foreboard, back plate and two Opposite side plate, and top plate and bottom plate, foreboard, back plate and both side plate constitute accommodating space.An at least water inlet pipe, is configured at shell The top plate of body is outer and is connected to accommodating space.Two outlet pipes are configured at outside the foreboard of shell and are connected to accommodating space.Multiple groups heat radiating fin Piece is configured in accommodating space and is spaced apart from each other.Wherein, at least two circulation roads, at least two circulation roads point are constituted in accommodating space Dui Ying not be to two outlet pipes, the axial direction of the axial direction of two outlet pipes and an at least water inlet pipe has the angle between 70 degree to 110 degree.

Based on above-mentioned, the liquid cooling radiator of the utility model, at least axial direction of an outlet pipe and an at least water inlet pipe Axial direction there is the angle between 70 degree to 110 degree, therefore, can be for when coolant liquid is from when at least a water inlet pipe enters shell Impinging cooling effect is generated at the part backplane of shell, with heat radiation effect.In addition, through the configuration of at least two circulation roads, So that coolant liquid is obtained preferable flow distribution, allows coolant liquid quickly through each group radiating fin with this and take away waste heat simultaneously, most Coolant liquid after final rise temperature leaves shell by an at least outlet pipe, and then reaches the mesh for promoting the heat transfer property energy of liquid cooling radiator 's.

Detailed description of the invention

Figure 1A is the appearance diagram of the liquid cooling radiator of an embodiment of the present invention；

Figure 1B is painted the perspective diagram of the liquid cooling radiator of Figure 1A；

Fig. 1 C is painted the Section A-A stereoscopic schematic diagram of the liquid cooling radiator of Figure 1A；

Fig. 1 D is painted the section B-B stereoscopic schematic diagram of the liquid cooling radiator of Figure 1A；

Fig. 1 E is painted the plane schematic side view of the liquid cooling radiator of Fig. 1 D；

Fig. 2A is the floor map of the liquid cooling radiator of another embodiment of the utility model；

Fig. 2 B is the floor map of the liquid cooling radiator of another embodiment of the utility model.

Description of symbols

100,100A, 100B: liquid cooling radiator；

110,110a, 110b: shell

111,111a, 111b: top plate

112,112a, 112b: bottom plate

113,113a, 113b: foreboard

114,114a, 114b: back plate

115: side plate

120,120A, 120B: water inlet pipe

130,130A, 130B: outlet pipe

140,140A, 140B: radiating fin

150,150A: partition

151A: end

160,160A, 160B: water conservancy diversion fin

170,170A, 170B: auxiliary fin

200: heat source

AS: accommodating space

A1, A2: axial

LD: length direction

H1, H2: vertical height

AN: angle

PA: circulation road

Specific embodiment

Aforementioned and other technology contents, feature and effect in relation to the utility model refer to the reality of attached drawing in following cooperation It applies in the detailed description of example, can clearly present.The direction term being previously mentioned in following embodiment, such as: upper and lower, left, It is right, front or rear etc., it is only the direction with reference to annexed drawings.Therefore, the direction term used is intended to be illustrative and not intended to limit The utility model.

Figure 1A is the appearance diagram of the liquid cooling radiator of an embodiment of the present invention.Figure 1B is painted the liquid cooling of Figure 1A The perspective diagram of formula radiator.Fig. 1 C is painted the Section A-A stereoscopic schematic diagram of the liquid cooling radiator of Figure 1A.Fig. 1 D is painted figure The section B-B stereoscopic schematic diagram of the liquid cooling radiator of 1A.Fig. 1 E is painted the plane side view signal of the liquid cooling radiator of Fig. 1 D Figure.

With reference to Figure 1A, the liquid cooling radiator 100 of the present embodiment is suitable for being configured on heat source 200, with for heat source 200 into Row heat dissipation, avoids the temperature of heat source 200 excessively high.Wherein heat source 200 be, for example, projector light source (such as light emitting diode or swash Light source made by the semiconductor subassemblies such as light), light valve, the central processing unit (CPU) of computer, graphics processor (GPU) or its It can generate the electronic building brick of high fever.Liquid cooling radiator 100 contacts the surface of heat source 200, and absorbs heat source through heat transfer Waste heat caused by 200 can reach cooling effect when heat source 200 operates, heat source 200 avoided to influence its fortune because temperature is excessively high Make.

Figure 1A to Fig. 1 C is please referred to, the liquid cooling radiator 100 of the present embodiment includes shell 110, at least a water inlet pipe 120, at least an outlet pipe 130, multiple groups radiating fin 140 and partition 150.

Shell 110 has top plate 111, bottom plate 112, foreboard 113, back plate 114 and two opposite side plates 115, and top plate 111, bottom plate 112, foreboard 113, back plate 114 and both side plate 115 constitute accommodating space AS.Wherein, the outer surface of bottom plate 112 is suitable In contact heat source 200.

In this present embodiment, the quantity of an at least water inlet pipe 120 is, for example, one, and water inlet pipe 120 is configured at shell 110 Top plate 111 is outer and is connected to accommodating space AS.In addition, the axial A1 of water inlet pipe 120 is, for example, the bottom plate 112 perpendicular to shell 110 With heat source 200, coolant liquid 300 is suitable for axially A1 out of, water inlet pipe 120 flows into shell 110 accommodating space AS.In addition, entering Water pipe 120 is, for example, to be located at top plate 111 close to the side of back plate 114.In addition, in other embodiments, the quantity of water inlet pipe Can be it is multiple, depending on the specification of liquid cooling radiator or demand.

The quantity of an at least outlet pipe 130 is, for example, one, and outlet pipe 130 is configured at outside the foreboard 113 of shell 110 and connects Logical accommodating space AS, and the axial A2 of outlet pipe 130 is parallel to the bottom plate 112 of shell 110, the i.e. bottom of outlet pipe 130 and shell There is spacing distance between the bottom plate 112 of body 110.In addition, outlet pipe 130 is, for example, the centre positioned at foreboard 113, and it is discharged The axial A2 of pipe 130 intersects at the axial A1 of water inlet pipe 120, and coolant liquid 300 flows out shell from outlet pipe 130 suitable for axially A2 Body 110.Specifically, the axial A1 of the axial A2 of outlet pipe 130 and water inlet pipe 120 has the angle between 70 degree to 110 degree AN, this illustrates that the axial A1 of water inlet pipe 120 is directed to the bottom plate 112 of shell 110.

Multiple groups radiating fin 140 (being two groups in the present embodiment) is configured in accommodating space AS and is spaced apart from each other.Each group dissipates Hot fin 140 is connected between the top plate 111 of shell 110 and bottom plate 112, i.e. the both ends of radiating fin 140 are born against in top Plate 111 and bottom plate 112.Furthermore, two groups of radiating fins 140 are located at the two sides of water inlet pipe 120, so that each group radiating fin 140 are separated from each other with water inlet pipe 120, when coolant liquid 300 is flowed into from water inlet pipe 120, can avoid directly touching radiating fin 140 And cause the feed pressure of coolant liquid 300 excessive.Since water inlet pipe 120 is bottom plate 112 downward towards shell 110, in cooling After liquid 300 passes through water inlet pipe 120, accommodating space AS can be entered and directly touch bottom plate 112, to generate impinging cooling effect. In addition, in this present embodiment, each group radiating fin 140 includes plate type fins, column fin or other shapes of fin.

In other embodiments, each group radiating fin is, for example, multilayered structure, i.e., each group radiating fin not be one at Type, but be made of multiple independent mutual storehouses of heat-sink unit.

Partition 150 is configured in accommodating space AS and between multiple groups radiating fin.Specifically, partition 150 is worn The foreboard 113 and back plate 114 of shell 110, interval are parallel in the length direction LD of two groups of radiating fins 140, and partition 150 Plate 150 is identical relative to foreboard 113 and the spacing distance of back plate 114, and is rendered as U-shaped time in constituting in accommodating space AS The two circulation road PA on road.The length direction LD of partition 150 be also respectively perpendicular to outlet pipe 130 and water inlet pipe 120 axial A2, A1 makes two circulation road PA be rendered as symmetric form, and 300 flow of coolant liquid having the same.In addition, the dislocation of partition 150 is in entering Water pipe 120, when axially A1 enters shell 110 from water inlet pipe 120 to coolant liquid 300, coolant liquid 300 touches bottom plate first 112, then by back plate 114 and partition 150 blocking and the direction that is respectively facing opposite both side plate 115 flows into two circulation roads PA, coolant liquid 300 flows along the two circulation road PA in U-shaped circuit and by corresponding radiating fin 140, and then reaches flowing point With the effect of.Final coolant liquid 300 is converged between foreboard 113 and partition 150, and axially A2 is left by outlet pipe 130 Shell 110 completes the flow circuit of a coolant liquid 300.

With reference to Fig. 1 C to Fig. 1 E, liquid cooling radiator 100 includes multiple water conservancy diversion fins 160 and at least one auxiliary fin 170. Multiple water conservancy diversion fins 160 and configuration are between partition 150 and the back plate 114 of shell 110.Multiple water conservancy diversion fins 160 to be located at into It water pipe 120 and is rendered as radial.Multiple water conservancy diversion fins 160 are respectively facing two circulation road PA and are obliquely extended, and cold to guide But liquid 300 forward flows into two circulation road PA respectively, avoids coolant liquid 300 because of collision back plate 114, partition 150 and radiating fin 140 and generate turbulent flow, reflux phenomena such as, this is unfavorable for the flowing of coolant liquid 300, also influences heat dissipation effect.

In this present embodiment, at least one auxiliary fin 170 quantity be one, configuration on bottom plate 112 and be located at every Between plate 150 and foreboard 113.The thickness of fin 170 is wherein assisted to be less than the thickness of each group radiating fin 140.Assist fin 170 To outlet pipe 130 is located at, that is, it is arranged between two groups of radiating fins 140.Further, since auxiliary fin 170 top T-phase for The vertical height H1 of bottom plate 112 is equal to or less than vertical height H2 of the bottom B of outlet pipe 130 relative to bottom plate 112, works as cooling When liquid 300 contacts auxiliary fin 170 by each group radiating fin 140, auxiliary fin 170 will not stop coolant liquid 300 to flow to Outlet pipe 130.Specifically, assist fin 170 is mainly used for bottom plate 112 of the reinforcement between partition 150 and foreboard 113 Heat transfer property energy inhaled when being flowed to along two circulation road PA close to the bottom plate 112 of the place of outlet pipe 130 due to coolant liquid 300 Waste heat and heating of the conduction of heat source 200 to two groups of radiating fins 140 are taken, then heat dissipation function of the coolant liquid 300 for bottom plate 112 herein Effect has glided, this waste heat that will lead to heat source 200 concentrates bottom plate 112 here, and generates high temperature.It, can by assisting fin 170 The heat transfer property energy for further promoting bottom plate 112 herein, avoids waste heat from concentrating and generate high temperature.

Other embodiments will be enumerated below to explain.It should be noted that, following embodiments continue to use aforementioned implementation herein Wherein indicating identical or approximate component using identical label, and phase is omitted in the component label and partial content of example With the explanation of technology contents.Explanation about clipped can refer to previous embodiment, and following embodiment will not be repeated herein.

Fig. 2A is the floor map of the liquid cooling radiator of another embodiment of the utility model.Please refer to Fig. 2A, this reality 100 difference of liquid cooling radiator of the liquid cooling radiator 100A and above-described embodiment that apply example are:

At least quantity of an outlet pipe 130A of the liquid cooling radiator 100A of the present embodiment is two, and two outlet pipes 130A is arranged at intervals on outside the foreboard 113a of shell 110A.Water inlet pipe 120A is arranged on top plate 111a and close to back plate 114a's Side, partition 150A are arranged between two groups of radiating fin 140A to constitute two circulation road PA.The length direction LD of partition 150A It is parallel to the axial A2 of each outlet pipe 130A, and the end 151A of partition 150A is connected to the foreboard 113a of shell 110A, and position Between two outlet pipe 130A.Furthermore, multiple water conservancy diversion fin 160A water inlet pipe 120A and are rendered as radial to being located at It is configured at bottom plate 112a, and is respectively facing two circulation road PA and is obliquely extended.In short, coolant liquid 300 enters from water inlet pipe 120A Shell 110A generates impinging cooling effect for bottom plate 112a, and then coolant liquid 300 is guided by multiple water conservancy diversion fin 160A and distinguishes Two circulation road PA are flowed into, and flow to corresponding outlet pipe 130A, to leave shell 110A.

Fig. 2 B is the floor map of the liquid cooling radiator of another embodiment of the utility model.

The liquid cooling radiator 100B of the present embodiment and the liquid cooling radiator 100A of above-described embodiment are close, but difference exists In:

The liquid cooling radiator 100B of the present embodiment has two outlet pipe 130B, and two outlet pipe 130B are arranged at intervals on shell Outside the foreboard 113b of body 110B.Water inlet pipe 120B configures the centre in top plate 111b.Multiple water conservancy diversion fin 160B to be located at into Water pipe 120B and radial configuration is rendered as in bottom plate 112b, and the two circulation road PA for being respectively facing shell 110B are obliquely extended. Two auxiliary fin 170B, configure on bottom plate 112b and between the back plate 114b and foreboard 113b.Furthermore, two It assists fin 170B to be located on the outside of the multiple groups radiating fin 140B and aligns two respectively in outlet pipe 130B, to promote bottom plate The heat radiation function of 112b.In short, coolant liquid 300 enters shell 110B from water inlet pipe 120B, for the centre of bottom plate 112a Impinging cooling effect is generated, then coolant liquid 300 is guided by multiple water conservancy diversion fin 160B and flows into two circulation road PA, and flows to correspondence Two outlet pipe 130B, to leave shell 110B.The liquid cooling radiator 100B of the present embodiment can not have to configuration partition, utilize The setting position of water inlet pipe 120B and water conservancy diversion fin 160B and make coolant liquid 300 enter shell 110B in after can towards two circulation Road PA is shunted.

Based on above-mentioned, the liquid cooling radiator of the utility model, at least axial direction of an outlet pipe and an at least water inlet pipe Axial direction there is the angle between 70 degree to 110 degree, therefore, can be for when coolant liquid is from when at least a water inlet pipe enters shell Impinging cooling effect is generated at the part backplane of shell, with heat radiation effect.In addition, making through the configuration of two circulation roads Coolant liquid obtains preferable flow distribution, allows coolant liquid quickly through each group radiating fin with this and takes away waste heat simultaneously, finally Coolant liquid after heating is converged and leaves shell by an at least outlet pipe, and then reaches the heat transfer property energy for promoting liquid cooling radiator Purpose.

Furthermore, the liquid cooling radiator of the utility model also has water conservancy diversion fin and auxiliary fin, water conservancy diversion fin It can be unfavorable for coolant flow with generating in flow process because colliding back plate, partition and radiating fin to avoid coolant liquid Turbulent flow, reflux phenomena such as.Heat transfer property energy of the fin to promote bottom plate is assisted, the waste heat of heat source is avoided to concentrate on the spy of bottom plate Determine region and generates high temperature.By the utility model embodiment compared with known techniques carry out simulation, the liquid-cooled of the utility model Radiator is under identical heat source and overall dimensions, and compared to known radiator, thermal resistance decline 14%, pressure drop also reduces by 7%.

The above, the only preferred embodiment of the utility model are implemented when that cannot limit the utility model with this Range, i.e., generally according to simple equivalence changes made by the utility model claims book and specification and modification, all still belong to In the range of the utility model patent covers.In addition any embodiment or claim of the utility model are not necessary to reach originally practical Novel disclosed whole purposes or advantage or feature.In addition, abstract part and denomination of invention are intended merely to auxiliary patent document Retrieval is used, and not is used to limit the interest field of the utility model.In addition, referred in this specification or claim The terms such as " first ", " second " are not only to name the title or the different embodiments of difference or range of element (Element) For the quantitative upper limit of restriction element or lower limit.

Claims (18)

1. a kind of liquid cooling radiator characterized by comprising shell, at least a water inlet pipe, at least an outlet pipe, multiple groups dissipate Hot fin and partition；Wherein,

The shell has top plate and bottom plate, foreboard, back plate and a two opposite side plates, and the top plate, the bottom plate, described Foreboard, the back plate and the both side plate constitute accommodating space；

An at least water inlet pipe is configured at outside the top plate of the shell and the connection accommodating space；

An at least outlet pipe is configured at outside the foreboard of the shell and the connection accommodating space；

The multiple groups radiating fin is configured in the accommodating space and is spaced apart from each other；And

Partition configuration in the accommodating space, and the partition between the multiple groups radiating fin in the appearance Empty interior composition at least two circulation roads；

Wherein, at least axial direction of an outlet pipe and the axial direction of an at least water inlet pipe have between 70 degree to 110 degree Angle, the partition dislocation is in an at least water inlet pipe.

2. liquid cooling radiator according to claim 1, which is characterized in that the length direction of the partition is respectively perpendicular to The axial direction of an at least outlet pipe.

3. liquid cooling radiator according to claim 1, which is characterized in that an at least outlet pipe is two, described The length direction of partition is parallel to the axial direction of each two outlet pipe, and the end abutment of the partition in the foreboard and is located at institute It states between two outlet pipes.

4. liquid cooling radiator according to claim 1, which is characterized in that further include multiple water conservancy diversion fins, configure in institute It states between partition and the back plate, and to positioned at an at least water inlet pipe.

5. liquid cooling radiator according to claim 4, which is characterized in that the multiple water conservancy diversion fin is rendered as radiating Shape, and be respectively facing at least two circulation roads and extend, when coolant liquid enters the shell from an at least water inlet pipe, institute Multiple water conservancy diversion fins are stated the coolant liquid is directed at least two circulation roads respectively and is radiated by the corresponding multiple groups Fin, and the shell is left by an at least outlet pipe.

6. liquid cooling radiator according to claim 1, which is characterized in that further include at least one auxiliary fin, configuration exists On the bottom plate and between partition and the foreboard, at least one auxiliary fin is to positioned at an at least outlet pipe.

7. liquid cooling radiator according to claim 6, which is characterized in that the top of at least one auxiliary fin is opposite It is equal to or less than vertical height of the bottom of an at least outlet pipe relative to the bottom plate in the vertical height of the bottom plate.

8. liquid cooling radiator according to claim 1, which is characterized in that an at least water inlet pipe is axially perpendicular to The bottom plate of the shell, the bottom plate for being axially parallel to the shell of an at least outlet pipe, the bottom plate are suitable In contacting a heat source.

9. liquid cooling radiator according to claim 1, which is characterized in that radiating fin described in each group is connected to the shell Between the top plate and the bottom plate of body.

10. liquid cooling radiator according to claim 1, which is characterized in that radiating fin described in each group includes plate fin Piece or column fin.

11. a kind of liquid cooling radiator characterized by comprising shell, at least a water inlet pipe, two outlet pipes and multiple groups dissipate Hot fin；Wherein,

The shell has top plate and bottom plate, foreboard, back plate and a two opposite side plates, and the top plate, the bottom plate, described Foreboard, the back plate and the both side plate constitute accommodating space；

An at least water inlet pipe is configured at outside the top plate of the shell and the connection accommodating space；

Two outlet pipe is configured at outside the foreboard of the shell and the connection accommodating space；And

The multiple groups radiating fin is configured in the accommodating space and is spaced apart from each other；

Wherein, at least two circulation roads are constituted in the accommodating space, at least two circulation roads are respectively corresponding to two water outlet The axial direction of pipe, the axial direction of two outlet pipe and an at least water inlet pipe has the angle between 70 degree to 110 degree.

12. liquid cooling radiator according to claim 11, which is characterized in that further include multiple water conservancy diversion fins, to being located at An at least water inlet pipe, centre of at least water inlet pipe configuration in the top plate.

13. liquid cooling radiator according to claim 12, which is characterized in that the multiple water conservancy diversion fin is rendered as radiating Shape, and be respectively facing at least two circulation roads and extend, when coolant liquid enters the shell from an at least water inlet pipe, institute Multiple water conservancy diversion fins are stated the coolant liquid is directed at least two circulation roads respectively and is radiated by the corresponding multiple groups Fin, and the shell is left by two outlet pipe.

14. liquid cooling radiator according to claim 11, which is characterized in that further include at least two auxiliary fins, configuration On the bottom plate and between the back plate and the foreboard, at least two auxiliary fin is located at the multiple groups heat radiating fin On the outside of piece and respectively to positioned at two outlet pipe.

15. liquid cooling radiator according to claim 14, which is characterized in that it is described two auxiliary fin top relative to The vertical height of the bottom plate is equal to or less than vertical height of the bottom of two outlet pipe relative to the bottom plate.

16. liquid cooling radiator according to claim 11, which is characterized in that an at least water inlet pipe it is axially vertical In the bottom plate of the shell, the bottom plate for being axially parallel to the shell of two outlet pipe, the bottom plate is suitable for Contact a heat source.

17. liquid cooling radiator according to claim 11, which is characterized in that radiating fin described in each group is connected to described Between the top plate and the bottom plate of shell.

18. liquid cooling radiator according to claim 11, which is characterized in that radiating fin described in each group includes plate fin Piece or column fin.