WO2007101693A1

WO2007101693A1 - Device for cooling, in particular, electronic components

Info

Publication number: WO2007101693A1
Application number: PCT/EP2007/002022
Authority: WO
Inventors: Steffen GRÖZINGER; Volker Velte; Henry Madsen; Henrik Olsen
Original assignee: Behr Industry Gmbh & Co. Kg; Noise Limit Aps
Priority date: 2006-03-09
Filing date: 2007-03-08
Publication date: 2007-09-13
Also published as: US20100005832A1; DE102006011333A1; EP1997140A1

Abstract

The invention relates to a device for cooling, comprising an evaporator, a gas cooler, a first coolant conduit for connecting an evaporator outlet to a gas cooler inlet, and a second coolant conduit for connecting a gas cooler outlet to an evaporater inlet.

Description

Device for cooling, in particular electronic components

The invention relates to a device for cooling in particular of electronic components according to the preamble of patent claim 1.

Such a cooling device is known from WO 2005/055319 A2. The known system has an evaporator for receiving heat of an electronic component and a capacitor for delivering the heat to the environment. From an outlet of the evaporator extends a riser, which opens into the condenser. In the riser, bubbles of vaporized refrigerant rise from the evaporator into the condenser, thus causing circulation of the refrigerant in the system. The end of the riser is located above a liquid level which is adjusted during operation.

It is an object of the present invention, in a device of the type mentioned to facilitate the circulation of a refrigerant in the device.

This object is achieved by a device for cooling with the features of claim 1. The basic idea of the invention is to reduce the flow resistance for a refrigerant circulating in the device by inserting a refrigerant line into the heat exchanger inlet on the heat exchanger inlet side and plugging it onto the heat exchanger outlet on the heat exchanger outlet side. As a result, bottlenecks for the refrigerant and / or vortex formation of the refrigerant are prevented or at least reduced, so that a circulation of the refrigerant is promoted in a cost-effective and simple structural manner.

Advantageous embodiments are the subject of the dependent claims and / or are explained in more detail below with reference to the drawings. Show it:

1 is a perspective view of a device for cooling electronic components,

2 is an exploded view of a device for cooling electronic components,

3 shows a side view of a device for cooling electronic components,

4 shows a longitudinal section of a device for cooling electronic components,

5 shows a cross section of a device for cooling electronic components,

6 shows a plan view of a device for cooling electronic components,

7 shows a longitudinal section of a distribution container of a gas cooler, 8 shows a side view of a device for cooling electronic components,

9 is a perspective view of a clamping device for pressing a heat sink to a heat-emitting component, and

Fig. 10 six side views of a clamping device for pressing a heat sink to a heat-emitting component.

1 shows a cooling device 110, which is provided for cooling a heat-emitting component, not shown, preferably a processor of a calculating machine. The cooling device 110 has an evaporator 120, a condenser 130, a first refrigerant line 140 and a second refrigerant line hidden in FIG. 1. The first refrigerant line 140 connects an evaporator outlet 150 to a concealed condenser inlet, and the second refrigerant line connects a concealed condenser outlet to a concealed evaporator inlet. The evaporator 120 is inserted into a clamping device 160 with which the cooling device 110 is clamped onto the heat-emitting component.

The capacitor 130 has a Befüllvoπichtung 165, which is soldered to a tubular distribution container of the capacitor 130. The capacitor 130 is sandwiched between a substantially rectangular cover 170 having a recess 180 and an axial fan 190.

The existing from the evaporator 120, the condenser 130 and the first and second refrigerant line refrigerant circuit is first evacuated before use via the filling device 165 and then filled with refrigerant, preferably using the known from the art refrigerant R134a is used.

In operation, the evaporator 120 transfers heat from the heat-emitting

Component on the refrigerant in it, which at least partially evaporated and via the first refrigerant line 140 in the condensate gate 130 arrives. The condenser 130 transfers heat from the refrigerant in it to air flowing convectively or driven by the axial fan 190 through a tube-fin block of the condenser 130 and through the recess 180. Thus, the refrigerant in the condenser 130 is cooled and optionally at least partially condensed. Subsequently, the refrigerant flows from the condenser 130 via the second refrigerant line back into the evaporator.

FIG. 2 shows an exploded view of a cooling device 210, which essentially corresponds to the cooling device 110 in FIG. 1. The cooling device 210 has an evaporator 220, a condenser 230, a first refrigerant line 240 and a second refrigerant line 245. The first refrigerant line 240 connects an evaporator outlet 250 to a concealed condenser inlet, and the second refrigerant line 245 connects a concealed condenser outlet to a concealed evaporator inlet.

The evaporator 220 is inserted into a tensioning device 260 with which the cooling device 210 in FIG. 2 is tensioned down onto the heat-emitting component. For this purpose, the tensioning device 260 has a first tension element 262 and a second tension element 263 as well as a tension web 264 arranged between the first and the second tension element. For pressing the cooling device 210 to the heat-emitting component, first formed as an eyelet and in Fig. 2 downwardly facing first tension member 262 mounted in a nose on the heat-emitting component or a frame part connected with her counterpart and then also trained as eyelet and downwardly facing second tension member 263 pushed down and also hooked into a counterpart, which acts on the clamping web 264, a clamping force on the inserted into a receptacle 266 of the clamping web 264 evaporator 220, which presses the evaporator to the heat-emitting component down. The clamping direction is thus in Figs. 1 and 2 down. The condenser 230 has a filling device 265, which is soldered to a tubular distribution container 232 of the capacitor 230. The capacitor 230 is enclosed between on the one hand a substantially rectangular cover 270 with a frame 275 enclosing the capacitor 230 and a recess 280 and on the other hand an axial fan 290.

In operation, the evaporator 220 transfers heat from the heat-emitting component to the refrigerant in it, which at least partially vaporizes via heat-conducting paste in a protective sleeve 222 and a cooling plate 224. For improved heat transfer, the cooling plate preferably has cooling elements, such as ribs, knobs or pins, which project into the evaporator to be flowed around by refrigerant. A lid 226 closes the evaporator 220 and optionally receives the cooling elements in it.

Via the first refrigerant line 240, the refrigerant passes into the condenser 230. The condenser 230 transfers heat from the refrigerant to air convective or driven by the axial fan 290 through a tube-fin block 234 of the condenser 230 and through the recess 280 of the cover 270 flows. The axial fan 290 has for this purpose a fan wheel with a hub 292, fan blades 294 and an outer ring 296, which rotates in a fan housing 298, driven by a hidden from the hub electric fan motor.

The refrigerant flows through a concealed capacitor inlet into the distribution vessel 232 of the condenser 230 and is distributed to the flat tubes 236 of the tube-and-fin block 232, which in turn are soldered into tube openings of the distribution vessel 232. After a heat transfer to the air flowing around the ribs 237, the cooled and possibly condensed refrigerant is collected in the collecting container 238 and then flows back into the evaporator 220 via a condenser outlet via the second refrigerant line 245. The condenser 230 and preferably also the evaporator 230 and the first and second refrigerant lines are made of a metal, preferably aluminum, or an alloy, preferably aluminum alloy, and soldered. The cover 270, the individual parts of the axial fan 290 with the exception of the fan motor and / or the clamping device 260 are preferably made of plastic, preferably by an injection molding process.

3 shows a cooling device 310 in a side view. The cooling device 310 has an evaporator 320, a condenser 330, a first refrigerant line 340 and a second refrigerant line 345. The first refrigerant line 340 connects an evaporator exit 350 to a condenser inlet concealed by a cover 370, and the second refrigerant line 345 connects a concealed condenser exit to an evaporator entrance 352. An axial fan 390 connects to the condenser 330 and is proximate to the evaporator 320, so that between the axial fan 390 and the evaporator 320 no space for the application of a tensioning device remains.

In operation, the evaporator 320 transfers heat from a heat-emitting component via a cooling plate 324 to refrigerant therein, which at least partially vaporizes. A lid 326 closes the evaporator 320 and receives any existing cooling elements in it.

Via the first refrigerant line 340, the refrigerant passes into the condenser 330. The condenser 330 transfers heat from the refrigerant to air flowing convectionally or driven by the axial-flow fan 390 through the condenser 330. After a transfer of heat to the air, the cooled and optionally condensed refrigerant flows via a capacitor outlet into the second refrigerant line 345 and from there back into the evaporator 320. The circulation of the refrigerant is indicated in FIG. 3 by arrows.

In order to promote a circulation of the refrigerant in the desired manner, the evaporator outlet 350 is geodetically higher than the evaporator inlet. gear 352 arranged. Since possibly vapor bubbles in the refrigerant in the evaporator rise upward, thus a transfer of the vapor bubbles via the evaporator outlet 350 is supported in the first refrigerant line 340, a passage of the vapor bubbles through the evaporator inlet 352 in the second refrigerant line 345, however, hindered.

Moreover, the circulation of the refrigerant is assisted in that the first refrigerant passage 340 has a diameter preferably larger by about one quarter than the second refrigerant passage 345. Advantageously, a diameter of 10 mm for the first refrigerant passage 340 and a diameter of 8 mm for the second refrigerant line.

Also advantageous for the circulation of the refrigerant are the at least horizontal course and largely steady rise of the first refrigerant line 340 from the evaporator outlet 350 to the condenser inlet and the steady gradient of the second refrigerant line 345 from the condenser exit to the evaporator inlet 352.

4 shows a cooling device 410 in a longitudinal section. The cooling device 410 has an evaporator 420, a condenser 430, a first refrigerant line 440 and a second refrigerant line 445. The first refrigerant line 440 connects an evaporator outlet 450 with a condenser inlet 455, and the second refrigerant line 445 connects a condenser outlet 458 with an evaporator inlet arranged in front of the drawing plane and therefore not visible.

Via the first refrigerant line 440, a refrigerant shown in black passes from the evaporator 420 via the evaporator outlet 450, the first refrigerant line 440 and the condenser inlet 455 into a substantially cylindrical distribution container 432 of the condenser 430. The condenser 430 transfers heat from the refrigerant to air, which flows through the tube-and-fin block 434 of the condenser 430. After heat transfer to the air, the cooled and optionally condensed refrigerant is collected in a sump 438 and flows via the condenser outlet 458 into the second refrigerant line 445 and from there back into the evaporator 420.

In order to promote a circulation of the refrigerant in the desired manner, the evaporator outlet 450 is arranged geodetically higher than the evaporator inlet. In addition, the circulation of the refrigerant is assisted in that the first refrigerant line 440 has a diameter that is preferably larger by a factor of about one fourth than the second refrigerant line 445. Advantageously, a diameter of 10 mm for the first refrigerant line 440 and a diameter of 8 mm for the second refrigerant line. Also advantageous for the circulation of the refrigerant are the at least horizontal course and mostly steady rise of the first refrigerant line 440 and the steady slope of the second refrigerant line 445.

It is advantageous to reduce the flow resistance for the refrigerant circulating in the cooling device 410 by inserting the first refrigerant line 440 into the condenser inlet 455 with a projection and plugging it onto the evaporator outlet 450. A similar advantage is achieved in that the second refrigerant line 445 is inserted into the evaporator inlet with a supernatant and plugged onto the capacitor output 458. As a result, bottlenecks for the refrigerant and / or vortex formation of the refrigerant are prevented or at least reduced, so that the circulation of the refrigerant is promoted in the desired direction in a cost-effective and simple structural manner. By plugging in some circumstances a backflow condensed refrigerant in the first refrigerant line 440 or evaporating refrigerant in the second refrigerant line 445 avoided or at least slowed down.

A simple construction may be provided by the provision of an outwardly projecting collar 451 on the evaporator exit 450 and / or an outwardly projecting collar 459 on the condenser exit 458. Preferably, the collar 451 and collar 459 each have a similar or larger internal diameter than the first reference - wise second refrigerant line, so no bottleneck for the refrigerant arises. The first and second refrigerant lines then have a first flared pipe end 441 or a second flared pipe end 446 with internal dimensions that correspond to the outer dimensions of the collar 451 or of the collar 459 for attachment.

FIG. 5 shows a cooling device 510 in a cross section, which essentially corresponds to the cooling device 410 in FIG. 4. The cooling device 510 has an evaporator 520, a condenser 530, a first refrigerant line not arranged in the drawing plane, and a second refrigerant line 545. The second refrigerant line 545 connects a condenser outlet 558 with an evaporator inlet 552 and leaves the drawing plane in sections and is therefore not completely shown.

In the collecting container 558 of the condenser 530, tube openings 531 are provided, into which flat tubes 536 are inserted and soldered. The flat tubes 536 are divided by longitudinal dividing walls 539 into flow channels 535, wherein the flow channels 535 are partially filled with refrigerant during a condensation of the refrigerant and in which condensed refrigerant is also cooled.

A simple construction may be provided by the provision of an outwardly projecting collar 559 at the condenser exit 558. Preferably, the collar 459 has a similar or greater internal diameter than the second refrigerant conduit 545 so that there is no bottleneck for the refrigerant. The second refrigerant line 545 has a second flared pipe end 546 with inner dimensions corresponding to the outer dimensions of the collar 459 for attachment.

6 shows a cooling device 610, which is provided for cooling a heat-emitting component, not shown, preferably a processor of a calculating machine. The cooling device 610 has an evaporator 620, a condenser 630, a first refrigerant line 640, and a second refrigerant line 645. The evaporator 620 is in a Spannvoπichtung 660 used with the cooling device 610 is stretched on the wäπmeabgebende component.

The condenser 630 has a Befüllvoπichtung 665, which is soldered to a tubular distribution container 632 of the capacitor 630. The capacitor 630 is enclosed between a cover, not shown, and an axial fan 690.

The existing from the evaporator 620, the condenser 630 and the first and second refrigerant line refrigerant circuit is first evacuated before use via the filling device 665 and then filled with refrigerant.

FIG. 7 shows the section A-A from FIG. 6. The distribution container 632 has a capacitor input 655 for inserting and soldering in the first refrigerant line 640 and a filling opening 656 for soldering the filling device 665. The substantially cylindrical filling device 665 is arranged as a nozzle on the longitudinal side of the tubular distribution container 632.

For filling the cooling device 610, a third refrigerant line is connected to a valve housing 666 of the filling device 665 designed as a valve by screwing a coupling element arranged at the end of the third refrigerant line onto the valve housing 666. In this case, the coupling element displaces a valve insert 668 in a channel 669 in Fig. 7 to the left in a filling position, wherein a spring element not shown within the valve core 668, which is supported via a stop element 667 at the filling opening 656 of the distribution container 632 or on the valve housing 666 , is tense.

The cooling device 610 is first evacuated via the channel 669 and the third refrigerant line released through the valve insert 668 in the filling position, and then filled with refrigerant via the third refrigerant line and the channel 669. Subsequently, the coupling element is unscrewed again from the filling device, wherein the spring element in the valve insert 668, possibly supported by an overpressure of the refrigerant in the cooling device 610, the valve insert 668 moves in Fig. 7 to the right in a closed position in which the valve core 668 the channel 669 blocks and seals by means of at least one sealing ring.

FIG. 8 shows the cooling device 610 from FIG. 6 in a side view. The tube-ribbed network 634 is arranged between the cylindrical distribution container 632 and a likewise cylindrical collecting container 638 of the condenser 630. The filling device is arranged at right angles to the tube-rib network on the distribution container. As a result, a space-saving design with good accessibility of the filling is achieved.

9 shows a tensioning device 910, which is provided for pressing a heat sink onto a heat-emitting component, for example to a processor of a calculating machine, in a perspective view. The tensioning device 910 has a first tension element 920 and a second tension element 930 as well as a tension web 940 arranged therebetween. The clamping web 940 has a receptacle 950 for a heat sink and a concealed first holding element 960 and a second holding element 970.

For pressing the heat sink to the heat dissipating component, first the heat sink in FIG. 9 is inserted from above into the receptacle. A lateral first projection of the heat sink is thereby pushed under the holding element 960 formed as a shoulder, after which a first projection opposite the second projection of the heat sink is pressed under the second holding element 970. This is made possible by an elastic retraction of the rear part web 945 of the clamping web 940 and facilitated by an inclined ramp 975 of the second holding element 970. In the case of using an evaporator according to one of FIGS. 1 to 8 as a heat sink, for example, a supernatant of the cooling plate relative to the lid of the evaporator serves as a projection.

Advantageously, the heat sink has a stop for the clamping device 910 upwards, so that the clamping device 910 after putting the heat sink is fixed in the receptacle 950 on the heat sink. In the case of using an evaporator according to one of FIGS. 1 to 8 as a heat sink, for example, the first and / or second refrigerant line fixedly connected to the evaporator and used as a stop serves as a stop.

The heat sink assembly obtained in this way is finally tensioned onto the heat-emitting component or a frame connected to it, for example an electronic circuit board. For this purpose, first designed as a downwardly facing eyelet first pulling element 920 mounted in a nose on the frame and then the second tension member 930 depressed and also hooked into a nose. In order to facilitate the depression, the clamping device 910 has a receptacle 980 for a tool, such as a screwdriver, in the region of the second pulling element 930.

10 shows six side views of a tensioning device 1010 that substantially corresponds to the tensioning device 910 in FIG. 9, from six different sides. The tensioning device 1010 has a first tension element 1020 and a second tension element 1030 as well as a tension web 1040 arranged therebetween. The clamping web 1040 has a receptacle 1050 for a heat sink and a first holding element 1060 and a second holding element 1070.

For pressing the heat sink to the heat-emitting component, the heat sink is first inserted in the clamping direction in the recording. A lateral first projection of the heat sink is thereby pushed under the holding element 1060 designed as a shoulder, after which a second projection of the heat sink opposite the first projection is pressed under the second holding element 1070. This is made possible by an elastic receding of the rear part web 1045 of the clamping web 1040 and facilitated by an inclined ramp 1075 of the second holding element 1070.

The heat sink assembly obtained in this way is finally applied to the heat-emitting component or a frame connected to it, For example, an electronics board, stretched. For this purpose, first designed as a downwardly facing eyelet first pulling element 1020 mounted in a nose on the frame and then the second tension member 1030 depressed and also hooked into a nose. In order to facilitate the depression, the clamping device 1010 has a receptacle 1080 for a tool, such as a screwdriver, in the region of the second pulling element 1030.

In addition, the second pulling element 1030 is designed as a bow which can be pivoted outwards, preferably a metal bow, and has a projection 1035 as an assembly aid. The second traction element 1030 can thus be swung in the depressed state easily into the counterpart intended for this purpose, for example in a nose, and then released via the projection 1035. The clamping web 1040 is then tensioned and generates a clamping force, which is transmitted via the tension elements as a tensile force and via the heat sink as compressive force on the heat-emitting component, so that a sufficient heat transfer from the heat-emitting component is ensured on the heat sink.

The invention has been described by way of example with reference to a cooling device for an electronic component, but is not limited to the described embodiments. It should be noted that the present invention is otherwise applicable. All described objects can be combined with each other. Likewise, all features of each item described are arbitrarily combinable or replaceable with all the features of the other items.

Claims

Patent claims

1. Apparatus for cooling, in particular of electronic components, in particular a processor unit, with an evaporator for absorbing heat in a refrigerant, in particular by evaporation, with a gas cooler for cooling the refrigerant, in particular by condensation, with a first Kältemittellertung for communicating a connection Evaporator outlet with a gas cooler inlet, with a second refrigerant line for communicating a gas cooler outlet with an evaporator inlet, characterized in that the first refrigerant line is plugged onto the evaporator outlet and / or inserted into the gas cooler inlet with a supernatant and that the second refrigerant line to the gas cooler outlet plugged and / or inserted into the evaporator inlet with a supernatant.

2. Device according to claim 1, characterized in that the gas cooler or the evaporator has a distribution container and a collecting container, wherein the gas cooler or evaporator inlet is arranged on the distribution container and the gas cooler or evaporator outlet to the collecting container, and wherein the distribution container and the Have collecting tube openings, are plugged into the refrigerant tubes or attached to the refrigerant tubes, wherein the refrigerant tubes are formed in particular as flat tubes with interposed corrugated fins.

3. Device according to one of the preceding claims, characterized in that the evaporator outlet or the gas cooler outlet has an outwardly projecting collar on the one Pipe end of the first and second refrigerant pipe is plugged, wherein the outer dimensions, such as outer diameter of the collar to the inner dimensions, such as inner diameter of the pipe end.

4. Device according to one of the preceding claims, characterized in that the tube end of the first or second refrigerant line is widened with respect to the remaining first or second refrigerant line, so that the inner diameter of the collar is substantially equal to or greater than an inner diameter of the remaining first or second refrigerant line ,

5. Device according to one of the preceding claims, character- ized in that the distribution container and / or the collecting container is tubular, in particular cylindrically formed.

6. Device according to one of the preceding claims, characterized in that the first or the second refrigerant line is inserted end face in the tubular distribution container.

7. Device according to one of the preceding claims, characterized in that the first or the second refrigerant line is longitudinally inserted into the tubular distribution container.

8. Device according to one of the preceding claims, characterized in that the first or the second refrigerant line is mounted on the front side of the tubular collecting container.

9. Device according to one of the preceding claims, characterized in that the first or the second refrigerant line is attached longitudinally on the tubular collecting container.

10. Device according to one of the preceding claims, characterized in that the tube openings are arranged longitudinally on the tubular distribution container or collecting container.

11. Device according to one of the preceding claims, characterized in that the first or the second refrigerant line opens substantially opposite the tube openings in the distribution container or collecting container.

12. Device according to one of the preceding claims, characterized in that the first or the second refrigerant line opens substantially at right angles to the tube openings in the distribution container or collecting container.

13. Device according to one of the preceding claims, characterized in that the device comprises a conveying device, such as fan, for the passage of a medium, in particular gas, in particular cooling air, through the gas cooler.

14. Device according to one of the preceding claims, characterized in that the device is provided for such a mounting in or on a heat-emitting component, that the gas cooler is arranged geodetically higher than the evaporator, so that the refrigerant by itself by evaporation from the evaporator Gas cooler and after condensation from the gas cooler to the evaporator flows.

15. Device according to one of the preceding claims, characterized in that the gas cooler inlet is arranged geodetically above the gas cooler outlet.

16. Device according to one of the preceding claims, characterized in that the gas cooler inlet to a geodetically upper end of the gas cooler or the distribution container is arranged.

17. Device according to one of the preceding claims, characterized in that the gas cooler outlet is arranged at a geodetically lower end of the gas cooler or the collecting container.

18. Device according to one of the preceding claims, characterized in that the evaporator outlet is arranged geodetically above the evaporator inlet.

19. Device according to one of the preceding claims, characterized in that the evaporator inlet is arranged at a geodetically lower end of the evaporator or the distribution container.

20. Device according to one of the preceding claims, characterized in that the evaporator outlet is arranged at a geodetically o beren the end of the evaporator or the collecting container.

21. Device according to one of the preceding claims, characterized in that the evaporator is provided for mounting on the heat-emitting component.