CN209299636U - Condenser and radiator - Google Patents
Condenser and radiator Download PDFInfo
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- CN209299636U CN209299636U CN201821370695.2U CN201821370695U CN209299636U CN 209299636 U CN209299636 U CN 209299636U CN 201821370695 U CN201821370695 U CN 201821370695U CN 209299636 U CN209299636 U CN 209299636U
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- base tube
- condenser
- mould group
- input
- evaporator
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Abstract
The utility model is about a kind of condenser and radiator, radiator includes condenser and evaporative component, condenser includes the main condenser mould group being sequentially arranged in series, connection tube and auxiliary condensation mould group, evaporative component includes evaporator, input pipe and efferent duct, the both ends of input pipe are separately connected the input base tube of evaporator and main condenser mould group, the both ends of efferent duct are separately connected the output base tube of evaporator and auxiliary condensation mould group, condenser and evaporative component is set to constitute a Closed Cycle circuit, and refrigerant is filled in Closed Cycle circuit, the radiator of the utility model is mainly by the way that main condenser mould group and auxiliary condensation mould group to be connected in series with each other, to extend the cooling path of required process when refrigerant passes through condenser, and provide secondary cooling and heat dissipation effect, enable gaseous coolant total condensation at liquid refrigerants, and then it can improve The efficiency of radiator.
Description
Technical field
The utility model be about a kind of condenser and radiator, espespecially to provide article or electronic device it is cooling and
The condenser and radiator of heat dissipation.
Background technique
Generally when using electronic device, electronic device temperature can gradually be promoted in operation, if the electronics
When the temperature of device is promoted to after a degree of high temperature still continued operation, the electronic device might have running it is abnormal,
Even there is the risk of damage parts therefore can be by installing a radiator, with thermal convection at the pyrotoxin of the electronic device
And the principles such as heat transfer distribute thermal energy caused by the pyrotoxin of electronic device, achieve the effect that cool whereby.
Wherein, the radiator mainly includes an evaporator and a condenser, and the evaporator is to be set to electronics dress
At the pyrotoxin set, which connects the evaporator with an evaporation tube and a return pipe, and constitutes a closed circulation loop,
Refrigerant is filled in the circulation loop, when the electronic device is when running, the pyrotoxin of the electronic device can generate heat,
And conduct makes the liquid refrigerants inside evaporator absorb heat and be vaporized into gaseous coolant to evaporator, and enters along the evaporation tube
The condenser, the gaseous coolant can cool down in the condenser and after re-condenses back into liquid form refrigerants, be back to steaming from the return pipe
It sends out in device to absorb heat again, through refrigerant in the phase transformation cyclic process of gaseous state and liquid, enables the pyrotoxin of electronic device
Reach heat dissipation effect whereby.
However radiator now only has a condenser, and the efficiency that the condenser can be provided cooling has
Limit, when refrigerant is when heat absorption is vaporized into gaseous coolant and passes through condenser, only having the gaseous coolant of part, to be condensed into liquid cold
Matchmaker, and all gaseous coolants can not be allowed all to be condensed into liquid refrigerants, cause the evaporating capacity of refrigerant to be increasingly greater than the condensation of refrigerant
Amount, and the problem for having radiating efficiency bad.
Utility model content
The purpose of this utility model is to provide a condenser and radiator, the uncommon radiator improved whereby now
Condenser can not make all gaseous coolants all be condensed into liquid refrigerants, and the evaporating capacity of refrigerant is caused to be increasingly greater than the condensation of refrigerant
Amount, and the problem for having radiating efficiency bad.
To take off purpose before reaching, condenser provided by the utility model includes:
One main condenser mould group, it includes an input base tube, one first connection base tube and a main cooling mechanism, the input base tubes
First connect base tube with this and be alternatively arranged setting, the main cooling mechanism be set to the input base tube with this first connect base tube it
Between;
One auxiliary condensation mould group, is arranged with the main condenser mould group interval, and it includes one second connection which, which condenses mould group,
Base tube, an output base tube and an auxiliary heat dissipation mechanism, the second connection base tube and the output base tube are alternatively arranged setting, the auxiliary
Cooling mechanism is set between the second connection base tube and the output base tube;And
One connection tube is set between the main condenser mould group and auxiliary condensation mould group, and the both ends of the connection tube are distinguished
Connect the first connection base tube and the second connection base tube, the connection tube can make the first connection base tube inner space and this
The inner space of two connection base tubes is in connected state by upper section to lower section.
Condenser as described above, wherein the main cooling mechanism includes multiple main heat radiation conduits and multiple main cooling fins, more
A main heat radiation conduit is set at interval in the upper and lower between the input base tube and the first connection base tube, multiple main cooling fins point
It is distributed between the adjacent two main heat radiation conduits, and the main cooling fin is contacted with the main heat radiation conduit in thermal conductivity;The auxiliary heat dissipation
Mechanism includes multiple auxiliary heat dissipation conduits and multiple auxiliary heat dissipation pieces, and multiple auxiliary heat dissipation conduits are set to this at interval in the upper and lower
Between second connection base tube and the output base tube, multiple auxiliary heat dissipation pieces are distributed between the adjacent two auxiliary heat dissipation conduits,
And the main cooling fin is contacted with the main heat radiation conduit in thermal conductivity respectively.
Condenser as described above, wherein form a plurality of linking runner in the connection tube, a plurality of linking runner respectively from
It is upper and under be alternatively arranged, and a plurality of linking runner is respectively communicated with the first connection base tube and second connect base tube with this.
The condenser of the utility model can provide refrigerant sequentially pass through the main condenser mould group and the auxiliary condensation mould group, with into
Row cooling provides the effect of article or device radiation cooling, wherein the condenser and radiator of the utility model are main whereby
It is connected in series with each other by the way that the main condenser mould group and the auxiliary are condensed mould group, to extend required process when refrigerant passes through condenser
Cooling path, and provide secondary cooling and heat dissipation effect, therefore when refrigerant is vaporized into gaseous coolant in heat absorption and passes through condensation
When device, it can enable that gaseous coolant is completely cooling, cools down and flows back to evaporation after being condensed into liquid refrigerants by longer cooling path
It in device, is avoided that the evaporating capacity of refrigerant is greater than the condensation number of refrigerant, and then improves heat dissipation effect of the refrigerant by the condenser when
Fruit.
Further, since the connection tube can make this first connection base tube inner space with this second connect base tube inside sky
Between by upper section to lower section be in connected state, therefore either float on this first connection base tube upper section gaseous coolant, also or
The liquid refrigerants for being deposited on the lower section of the first connection base tube can all pass through the connection tube and enter in the second connection base tube.
To take off purpose before reaching, radiator provided by the utility model includes:
One condenser as the aforementioned;And
One evaporative component forms an evaporation it includes an evaporator, an input pipe and an efferent duct inside the evaporator
Room, and the bottom of the evaporator has a conductive base plate, the both ends of the input pipe are separately connected the top of the evaporator and are somebody's turn to do
The input base tube of the main condenser mould group of condenser, the both ends of the efferent duct are separately connected the side wall and the condenser of the evaporator
Auxiliary condensation mould group output base tube, the evaporative component and the condenser constitute a Closed Cycle circuit, and this is closed
Refrigerant is filled in circulation loop.
Radiator as described above, wherein the upper section of the input base tube of the condenser forms a refrigerant inlet, the input
The both ends of pipe are separately connected the top of the evaporator and the refrigerant inlet of the input base tube, under the output base tube of the condenser
Section forms a refrigerant exit, and the refrigerant of side wall and the output base tube that the both ends of the efferent duct are separately connected the evaporator goes out
Mouthful.
Radiator as described above, wherein the lower section of the input base tube of the condenser forms a refluxing opening, and the evaporation
Component includes a return pipe, and the both ends of the return pipe are separately connected the side wall of the evaporator and the refluxing opening of the input base tube.
Radiator as described above, wherein the bore of the input pipe is greater than the bore of the efferent duct.
Radiator as described above, wherein the bore of the input pipe is greater than the bore of the efferent duct, and the input pipe
Bore is greater than the bore of the return pipe.
The evaporator of the radiator is to be set on the pyrotoxin of article or device, when pyrotoxin generates heat,
Refrigerant inside the evaporator can absorb the heat of pyrotoxin and be vaporized into gaseous coolant, and connect certainly defeated at the top of the evaporator
Enter pipe and flow into the condenser, the refrigerant can be during sequentially passing through the main condenser mould group and the auxiliary condenses mould group gradually
It is condensed into liquid refrigerants, and from the vaporization chamber that efferent duct flows back to evaporator, is absorbed heat again.
In addition, the lower section of the input base tube of the condenser forms a refluxing opening, and the evaporative component includes a return pipe, should
The both ends of return pipe are separately connected the side wall of the evaporator and the refluxing opening of the input base tube, when gaseous coolant is from input pipe
Into the input base tube, and when having part refrigerant condensed at liquid refrigerants, liquid refrigerants can be directly back to from the return pipe
In evaporator, by multithread to refrigerant phase transformation circulate mode, so that liquid, gaseous coolant is shunted really, can further mention
The heat dissipation effect of the high radiator.
Detailed description of the invention
Following drawings are only intended to schematically illustrate and explain the present invention, does not limit the model of the utility model
It encloses.Wherein:
Fig. 1: for a kind of preferred embodiment three-dimensional appearance schematic diagram of the condenser of the utility model.
Fig. 2: for the schematic top plan view of the condenser of the utility model.
Fig. 3: for the side view floor map of the condenser of the utility model.
Fig. 4: for a kind of three-dimensional appearance schematic diagram of preferred embodiment of the radiator of the utility model.
Fig. 5: the partial cutaway schematic on pyrotoxin is set to for the evaporator of the radiator of the utility model.
Fig. 6: for the flow direction schematic diagram (one) of the refrigerant of the radiator of the utility model.
Fig. 7: for the flow direction schematic diagram (two) of the refrigerant of the radiator of the utility model.
Specific embodiment
In order to have clearer understanding to the technical solution of the utility model, purpose and effect, now in conjunction with Detailed description of the invention sheet
The specific embodiment of utility model.
It please refers to Fig.1 to Fig.3, is a kind of preferred embodiment of the condenser of the utility model, it includes a main condenser moulds
10, one auxiliary condensation mould group 20 of group and a connection tube 30.
As shown in Figure 1 to Figure 3, which includes that an input base tube 11, one first connects base tube 12 and a master
Cooling mechanism 13, the input base tube 11 first connect base tube 12 and are alternatively arranged setting with this, which is set to this
It inputs between base tube 11 and the first connection base tube 12, wherein the main cooling mechanism 13 includes multiple main heat radiation conduits 14 and more
A main cooling fin 15, multiple main heat radiation conduits 14 are set to the input base tube 11 and the first connection base tube 12 at interval in the upper and lower
Between, multiple main cooling fins 15 are distributed between the adjacent two main heat radiation conduits 14, and the main cooling fin 15 and the main heat dissipation
Conduit 14 is contacted in thermal conductivity.
As shown in Figure 1 to Figure 3, auxiliary condensation mould group 20 and the main condenser mould group 10 interval are arranged, and connect comprising one second
It connects base tube 21, one and exports base tube 22 and an auxiliary heat dissipation mechanism 23, the second connection base tube 21 and the output base tube 22 interval are arranged
Column setting, the auxiliary heat dissipation mechanism 23 are set between the second connection base tube 21 and the output base tube 22, wherein the auxiliary dissipates
Heat engine structure 23 include multiple auxiliary heat dissipation conduits 24 and multiple auxiliary heat dissipation pieces 25, multiple auxiliary heat dissipation conduits 24 between the upper and lower every
Ground is set between the second connection base tube 21 and the output base tube 22, and multiple auxiliary heat dissipation pieces 25 are distributed in adjacent two, and this is auxiliary
It helps between heat radiation conduit 24, and the main cooling fin 15 is contacted with the main heat radiation conduit 14 in thermal conductivity.
As shown in Figure 1 to Figure 3, which is set between the main condenser mould group 10 and auxiliary condensation mould group 20,
The both ends of the connection tube 30 are separately connected the first connection base tube 12 and the second connection base tube 21, make the first connection base tube 12
Inner space second connect the inner space of base tube 21 by upper section to lower section in connected state with this, wherein the connection tube 30
Interior to form a plurality of linking runner 31, a plurality of linking runner 31 is alternatively arranged from top to bottom respectively, and a plurality of linking runner 31
It is respectively communicated with the first connection base tube 12 and second connect base tube 21 with this.
Referring to Fig. 4, a kind of preferred embodiment of the radiator for the utility model, it includes a condensations as the aforementioned
Device and an evaporative component 40.
As shown in Figure 4, Figure 5, which includes an evaporator 41, an input pipe 42 and an efferent duct 43, the steaming
A vaporization chamber 411 is formed inside hair device 41, and the bottom of the evaporator 41 has a conductive base plate 412, the two of the input pipe 42
End is separately connected the top of the evaporator 41 and the input base tube 11 of the main condenser mould group 10, the both ends difference of the efferent duct 43
Connect the side wall of the evaporator 41 and the output base tube 22 of auxiliary condensation mould group 20, the evaporative component 40 and the condenser structure
At a Closed Cycle circuit, and refrigerant 50 is filled in the Closed Cycle circuit.
Wherein, as Figure 1 and Figure 4, the upper section of the input base tube 11 of the condenser forms a refrigerant inlet 16, the input
The both ends of pipe 42 are separately connected the top of the evaporator 41 and the refrigerant inlet 16 of the input base tube 11, the output of the condenser
The lower section of base tube 22 forms a refrigerant exit 26, and the both ends of the efferent duct 43 are separately connected the side wall of the evaporator 41 and this is defeated
The refrigerant exit 26 of base tube 22 out, in addition, the lower section of the input base tube 11 of the condenser can be further formed a refluxing opening 17, and
The evaporative component 40 includes a return pipe 44, and the both ends of the return pipe 44 are separately connected side wall and input of the evaporator 41
The refluxing opening 17 of base tube 11, furthermore, the bore of the input pipe 42 is greater than the bore of the efferent duct 43, and the bore of the input pipe 42
Greater than the bore of the return pipe 44.
As shown in figure 5, the condenser of the utility model can be applied to general radiator or the radiator as before taken off,
And mould group 20 is condensed by the main condenser mould group 10 and the auxiliary and is serially connected, enable refrigerant 50 sequentially by the main condenser mould
Group 10 and auxiliary condensation mould group 20 are cooled down and are cooled down, and then provide the radiating and cooling effect of article or device.
As shown in Figures 5 to 7, by taking the radiator of the utility model is applied to the cooling and cooling of electronic device as an example,
The evaporator 41 of the radiator can be to be set to the pyrotoxin of the electronic device, when the pyrotoxin of electronic device issues
Heat and when increase temperature, the conductive base plate 412 of the evaporator 41 can conduct heat to vaporization chamber 411, make cold in vaporization chamber 411
The heat absorption of matchmaker 50 is vaporized into gaseous coolant 50, and the gaseous coolant 50 can flow into connection evaporation because of the principle that hot gas rises naturally
In the input pipe 42 at 41 top of device, and along the input base tube 11 of the entrance of the input pipe 42 main condenser mould group 10, then, the gas
State refrigerant 50 sequentially can be condensed mould group 20 and gradually be condensed by the main condenser mould group 10, the connection tube 30 and the auxiliary forms liquid
State refrigerant 50, finally the output base tube 22 from auxiliary condensation mould group 20 flows into the efferent duct 43 and is back in the evaporator 41
Again it absorbs heat.
As shown in Figures 5 to 7, the main condenser mould group 10 and auxiliary condensation mould group 20 are connected in series with each other, and can be extended cold
Matchmaker 50 enters the cooling path of required process when condenser, makes refrigerant 50 when entering in the condenser, can pass through the main condenser
The auxiliary heat dissipation mechanism 23 of the main cooling mechanism 13 of mould group 10 and auxiliary condensation mould group 20 provides secondary cooling and heat dissipation
Effect can effectively improve the cooling efficiency of refrigerant 50, make gaseous coolant 50 when passing through condenser, and energy total condensation is cold at liquid
Matchmaker 50, without having the problem of gaseous coolant 50 remains, are avoided that the evaporating capacity of refrigerant 50 is greater than the condensation number of refrigerant 50, in turn
Improve the radiating efficiency of the radiator.
Wherein, as shown in figure 3, the connection tube 30 can make inner space and second linker of the first connection base tube 12
The inner space of pipe 21 is in connected state by upper section to lower section, therefore either floats on the gas of the upper section of the first connection base tube 12
State refrigerant 50, also or the connection tube 30 can all be passed through by being deposited on the liquid refrigerants 50 of lower section of the first connection base tube 12
Into in the second connection base tube 21.
In addition, as shown in Figures 5 to 7, when gaseous coolant 50 is entering the main condenser mould group 10 by the input pipe 42
When inputting base tube 11, if there is the gaseous coolant 50 of part when being directly condensed into liquid refrigerants 50 after far from heat source, the liquid
Refrigerant 50 can flow to the lower section of the input base tube 11 directly down, and directly be back to the evaporator 41 from return pipe 44
In, and remaining gaseous coolant 50 then can sequentially be flowed along the main condenser mould group 10, the connection tube 30 and the auxiliary condensation mould group 20
It is dynamic, finally flowed back in evaporator 41 from the efferent duct 43, by multithread to refrigerant phase transformation circulate mode, make liquid, gaseous state
Refrigerant can shunt really, can be further improved the heat dissipation effect of the radiator.
In conclusion the radiator of the utility model mainly passes through the main condenser mould group 10 and auxiliary condensation mould group
20 are connected in series with each other, to extend the cooling path of required process when refrigerant 50 passes through condenser, and provide secondary cooling and
Heat dissipation effect makes gaseous coolant 50 after flowing into the condenser, and energy total condensation can improve the heat dissipation at liquid refrigerants 50
The efficiency of device.
The above descriptions are merely exemplary embodiments of the present utility model, the model being not intended to limit the utility model
It encloses.Any those skilled in the art, made equivalent change under the premise of not departing from the conceptions and principles of the utility model
Change and modify, should belong to the range of the utility model protection.And it should be noted that the utility model each component part
It is not limited in above-mentioned overall applicability, each technical characteristic described in the specification of the utility model can select according to actual needs
It selects one and individually uses or select the multinomial use that combines, therefore, the utility model covers and this crime in the nature of things
The related other combinations of bright point and concrete application.
Claims (8)
1. a kind of condenser, which is characterized in that the condenser includes:
One main condenser mould group, it includes an input base tube, an one first connection base tube and main cooling mechanism, the input base tube with should
First connection base tube is alternatively arranged setting, which is set between the input base tube and the first connection base tube;
One auxiliary condensation mould group, with the main condenser mould group interval be arranged, the auxiliary condense mould group include one second connection base tube,
One output base tube and an auxiliary heat dissipation mechanism, the second connection base tube and the output base tube are alternatively arranged setting, the auxiliary heat dissipation
Mechanism is set between the second connection base tube and the output base tube;And
One connection tube is set between the main condenser mould group and auxiliary condensation mould group, and the both ends of the connection tube are separately connected
The first connection base tube and the second connection base tube, the connection tube can make inner space and second company of the first connection base tube
The inner space of base tube is connect by upper section to lower section in connected state.
2. condenser as described in claim 1, which is characterized in that the main cooling mechanism includes multiple main heat radiation conduits and multiple
Main cooling fin, multiple main heat radiation conduits are set at interval in the upper and lower between the input base tube and the first connection base tube, multiple
The main cooling fin is distributed between the adjacent two main heat radiation conduits, and the main cooling fin connects with the main heat radiation conduit in thermal conductivity
Touching;The auxiliary heat dissipation mechanism includes multiple auxiliary heat dissipation conduits and multiple auxiliary heat dissipation pieces, above and below multiple auxiliary heat dissipation conduits
It is positioned apart between the second connection base tube and the output base tube, multiple auxiliary heat dissipation pieces are distributed in adjacent two auxiliary
Between heat radiation conduit, and the main cooling fin is contacted with the main heat radiation conduit in thermal conductivity respectively.
3. condenser as claimed in claim 1 or 2, which is characterized in that a plurality of linking runner is formed in the connection tube, it is a plurality of to be somebody's turn to do
Linking runner is alternatively arranged from top to bottom respectively, and a plurality of linking runner is respectively communicated with the first connection base tube and second company
Connect base tube.
4. a kind of radiator, which is characterized in that the radiator includes:
One condenser as claimed any one in claims 1 to 3;And
One evaporative component forms a vaporization chamber it includes an evaporator, an input pipe and an efferent duct inside the evaporator, and
The bottom of the evaporator has a conductive base plate, and the both ends of the input pipe are separately connected top and condenser of the evaporator
Main condenser mould group input base tube, the both ends of the efferent duct are separately connected the side wall of the evaporator and the auxiliary of the condenser
The output base tube of mould group is condensed, the evaporative component and the condenser constitute a Closed Cycle circuit, and the Closed Cycle returns
Refrigerant is filled in road.
5. radiator as claimed in claim 4, which is characterized in that the upper section of the input base tube of the condenser forms a refrigerant
Entrance, the both ends of the input pipe are separately connected the top of the evaporator and the refrigerant inlet of the input base tube, the condenser
The lower section for exporting base tube forms a refrigerant exit, and the both ends of the efferent duct are separately connected the side wall and the output base of the evaporator
The refrigerant exit of pipe.
6. radiator as claimed in claim 5, which is characterized in that the lower section of the input base tube of the condenser forms a reflux
Mouthful, and the evaporative component includes a return pipe, the both ends of the return pipe are separately connected the side wall and the input base of the evaporator
The refluxing opening of pipe.
7. radiator as described in claim 4 or 5, which is characterized in that the bore of the input pipe is greater than the mouth of the efferent duct
Diameter.
8. radiator as claimed in claim 6, which is characterized in that the bore of the input pipe is greater than the bore of the efferent duct,
And the bore of the input pipe is greater than the bore of the return pipe.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
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CN201821370695.2U CN209299636U (en) | 2018-08-24 | 2018-08-24 | Condenser and radiator |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
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CN201821370695.2U CN209299636U (en) | 2018-08-24 | 2018-08-24 | Condenser and radiator |
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Publication Number | Publication Date |
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CN209299636U true CN209299636U (en) | 2019-08-23 |
Family
ID=67651031
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
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CN201821370695.2U Active CN209299636U (en) | 2018-08-24 | 2018-08-24 | Condenser and radiator |
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CN (1) | CN209299636U (en) |
Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN111010847A (en) * | 2019-11-22 | 2020-04-14 | 广东工业大学 | Soaking plate type heat dissipation device |
-
2018
- 2018-08-24 CN CN201821370695.2U patent/CN209299636U/en active Active
Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN111010847A (en) * | 2019-11-22 | 2020-04-14 | 广东工业大学 | Soaking plate type heat dissipation device |
CN111010847B (en) * | 2019-11-22 | 2021-09-07 | 广东工业大学 | Soaking plate type heat dissipation device |
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