DE2824779A1 - Heat exchanger structure for electronic apparatus - has aluminium heat exchangers at air entry, and copper ones at exit where cooling air is warmest - Google Patents

Abstract

A chassis for an electronic appts. having heat generating circuit components attached to heat exchangers along its top and bottom walls. Each heat exchanger includes a base from which parallel fingers project toward a plane passing horizontally through the centre of the chassis, the various exchangers having fingers of differing lengths to define an air passage of varying effective cross-sectional area, promoting air turbulence for increased cooling. The heat exchangers at the entrace to the air passage are aluminium, while those at the exit where the cooling air is warmest are copper.

Description

Heat exchanger structure for electronic

Devices "The present invention relates to electronic devices and particularly to devices in which heat exchangers are along a passage or Channel for cooling air are attached, electronic components, especially those whose Operation requires relatively high performance, generate considerable amounts of heat, which must be effectively discharged, since the characteristics and parameters the components are not stable against heating beyond certain finite limits and since an increase in temperature generally leads to increased distortion. Modern semiconductor components take up relatively little space - and that for the heat radiation required between the components is thus one of the main factors that determine the overall size of a device.

In the power levels of devices such as audio-frequency amplifiers It is often difficult to dissipate the power, since this involves power transistors and diodes the main ones Form heat sources. In many cases it will Heat generated by these components is dissipated by heat emitters attached to the Inside of housing walls are attached; the heat is dissipated with cooling air, which is blown through the housing. As the size of the chassis decreases, it increases the temperature on and a greater fan power is required to produce a stronger one Maintain flow of cooling air. In general, however, it is desirable to keep the required fan power as low as possible in order to reduce noise, size and power consumption to reduce.

A main object of the present invention is to provide a more effective one Shape and arrangement of heat exchangers to create that the heat to a limited More effectively dissipate space and with certain performance parameters of the fan The present invention comprises an electronic device with heat generating components, which several heat exchangers are assigned, which in turn have a passage for Define cooling air with different effective cross-sections, so that the turbulence the cooling air is increased and the efficiency of the heat radiation increases. The invention is particularly suitable in the power levels of high quality Yon frequency amplifiers and fidelity and similar devices.

The heat exchangers are on the inner surfaces of two opposite one another Housing walls arranged; the base area every heat exchanger is attached to one of the walls and several heat radiating parts, preferably in the form of elongated, parallel finger processes, proceed from the base, The heat-generating components of the respective circuit are on the base mounted between the heat radiating parts. All can radiate heat Parts of a single heat exchanger are the same length but change the length from one heat exchanger to the next to achieve the desired profile of the Define passage channel.

In a preferred embodiment, the passage comprises one Vortex section next to the entrance to the housing and this section has one Cross-sectional area which decreases with distance from the inlet opening of the housing; the swirl section is followed by a diffuser or distributor section, which is the largest Has cross-sectional area in the passage. There is a next to the manifold section second swirl section, the cross-sectional area with the distance from the Outlet opening of the housing decreases. The alternating swirl and Distribution sections result in a mixing of the air flowing through the ducts, so that forwards and backwards directed air currents arise across the passage and increase the cooling effect. The heat exchangers in the part of the swirl section at the exit, where the cooling air is warmest, have the greatest length and are off Copper manufactured as it was the greatest heat dissipation possible; the other heat exchangers are made of aluminum.

Further features and advantages of the present invention emerge can be derived from the following detailed description with reference to the attached Drawings illustrating, by way of example, the basic idea of the invention.

Figure 1 is a cross-section through an exemplary electronic Apparatus in which the invention is used; the cross-section is perpendicular and against the center line of the device offset, parallel to the passage opening for the cooling air taken with the upper half-of the cross section symmetrical to the lower half and is therefore only indicated in its outlines.

Figure 2 is an end view of the device showing the exit port the passage for the cooling air.

Figure 3 is a partial cross-section of a portion of the top Half of the device along the line designated 3-3 in Figure 1.

Figure 4 is an enlarged perspective view of the heat exchanger of the device.

Finally, Figure 5 is an enlarged plan view of the heat exchanger.

The invention shown in the drawings can be used in electronic devices, for example in the power amplifiers of Hiili sound systems (systems with high Quality of reproduction) and results in increased turbulence in the cooling air, around thus improving heat dissipation. In general, the device includes a chassis or a frame 10, a fan or a blower 11 for blowing cooling air through through the chassis, several heat exchangers 12, a passage 13 for the cooling air between opposing heat exchangers and several heat generating components 14, which are attached to the heat exchangers.

As can be seen in Figure 1, the chassis 10 is generally rectangular and has opposite upper walls 15 and lower walls 16, as well two open ends 17 and 18, which have an inlet orifice for the cooling air.

Represent the outlet opening. The top and bottom halves of the chassis 10 can be separated from each other for easy assembly and repair of the device to be able to; the separation takes place along horizontal center lines 19 in the two vertical side walls 20 instead, the upper sections 20a and the lower Sections 20b of the side walls form an interlocking connection their entire length. Boards 21 with printed circuits are on the outer surface 22 of the upper wall 15 and the lower wall 16 attached. The fan 11 is attached to the inlet opening 17 and blows cooling air through the chassis 10 in Direction of its longer horizontal axis.

The heat exchanger parts 12 are with screws 23 on the opposite Inner surfaces 24 of the upper wall 15 and the lower wall 16 attached and so arranged that the arrangement to achieve vertical symmetry can repeat at the bottom and top of the chassis.

Each heat exchanger part 12 is more uniform from a single sheet of metal Thickness has been punched out and includes a flat bottom portion 25 that rests on a small part of the upper wall or lower wall of the chassis rests.

The heat exchanger part 12 also has several upright parts Heat radiation that takes the form of parallel, elongated, finger-like appendages 26 to have. The extensions 26 run perpendicular to the base and protrude in the direction a plane extending horizontally through the center plane of the chassis 10 runs. In the preferred embodiment, the heat exchanger parts have 12 twelve appendages combined in pairs. As can be seen from Figure 4, the Bottom section 25 at the two ends closest to which the projections of the pairs 26a come closest together; the widest part of the base is located in the middle section, in which the extensions 26b of two adjacent pairs are the largest Are spaced apart, the intermediate pairs of projections 26c apart by an intermediate amount. The base 25 has the one shown in FIG 5 illustrated step-shaped contour, so that the extensions of each pair in each case correct spacing. The length of the appendages varies 26 from one heat exchanger 12 to the next, as detailed below described. The appendages each individual heat exchanger but same length.

The components 14 representing strong heat sources, in which it are power transistors, diodes and other circuit elements each used in one of the heat exchangers 12 and shown in FIG Surrounded by the finger-like projections 26. Lines not shown extend from the components 14 through holes 27 in the bottom portion 25 of the Heat exchanger and go to the board 21 for the printed circuits, so that the individual components are connected to one another, holes 28, which in larger distances are provided in the bottom section 25, enable a connection with the chassis 10 with the aid of screws 23. The components 14 are in heat exchange with the parts 12, so that the heat generated by the components from the extensions 26 is emitted.

The vertically opposite, from the upper wall 15 and the lower wall 16 protruding extensions define between them Passage 13 through which cooling air can be blown freely from the fan 11. The approximate profile of the passage is shown in Figure 1 by the dashed lines A and B indicated. The area of a plane which is transverse to the passage 13 and perpendicular to the direction of the total flow of cooling air from the inlet opening 17 to the outlet opening 18 is located and can flow freely through the air without sticking to the sides of the appendages passing by forms the effective cross-sectional area of the passage, The air however, its movement is not restricted to this passage, but flows also constantly in the area of the extensions 26 of the heat exchanger and back into the passage.

The cross section of the passage 13 on the output side 18 of the housing is shown at the end in FIG.

When the air is straight through the passage 15 in laminar Flow would move without passing over the surfaces of the heat exchanger parts 12 being deflected, the heat would not be effective in the desired manner led off. The heat dissipation is, however, significantly improved by the turbulence the air in the passage 13, since this interrupts the laminar flow and any stagnation of cooling air in the passage 13 is prevented. A certain amount of turbulence results from the vortex movement that the fan 11 through its revolutions of Cooling air granted. According to the invention, however, the turbulence of the cooling air and thus their effect on the heat exchanger parts 12 is considerably increased by changes the lengths of the extensions 26 along the passage 13.

The heat exchanger parts 12 are arranged in rows 29a-29g, the run across the passage 15. The heat exchanger parts of a row do not need be completely aligned with one another, as in FIG. 2. The length of the port sets 26 of the three rows 29a-29c of the heat exchangers next to the inlet opening 17 to the housing 10 gradually increases from one row to the next, creating a first vortex section 30th is formed in the passage 13. The effective cross-sectional area of this first swirl section 30 decreases with increasing distance from the inlet opening 17. When the Cooling air in the passage 13 it is compressed and its speed is increased, resulting in increased swirl and turbulence, as indicated by arrows C and D indicated.

The turbulence can be increased in an advantageous manner when the Passage between the inlet opening 17 and the outlet opening 18 of the housing 10 has a swirling profile; however, the turbulence is further intensified by a manifold section 31, in which the passage profile of a single Row of heat exchangers 29d is defined. These have the shortest extensions 26, so that the passage 13 has the maximum cross-sectional area there.

The closest to the narrow end of the first turbulence section 30, distributor section located midway between the inlet opening and the outlet opening 18 31 causes the cooling air to expand outwards perpendicular to the direction of flow of the Cooling air through passage 13. This results in a larger vortex that passes through the arrow E in Figure 1 is indicated by t.

Next to the manifold section 31 at one end and the outlet port 18 at the other end is a second swirl section 32, which is from three rows 29e, 29f and 29g of heat exchangers 12 at the passage 13 are formed will. The effective cross-sectional area of the second swirl section 32 takes with it the distance from the opening from that opening 18 to thereby increase the turbulence and the cooling air as previously described in connection with swirl section 30, to put in turbulent motion.

Apart from the distributor section 31, the second swirl section 32 is a continuation of the first swirl section 30, the shortest Extensions 26 longer than the longest extensions of the first swirl section are. The cross-sectional area of the passage 13 is therefore at the mouth of the second Swirl section 32 next to the distributor section 31 is smaller than at the end of the first vortex section 30 next to the distributor section, when moving the cooling air through the passage 13 increases its temperature constantly and the The cooling effect decreases accordingly. This increase the temperature of the cooling air is partially compensated by the fact that with the exception of the heat exchanger 12 in the Distributor section 31 the length of the extensions 26 from the inlet port 17 to the outlet port 18 increases, there is thus a gradual increase in the radiating area with the increase in the temperature of the cooling air, in order to increase the cooling air temperature To compensate further, the heat exchangers of the two series 29f and 29g made at the outlet opening 18 of a metal that the heat stronger than that Metal from the other heat exchangers can flare. The ability of the metal warmth starting from is defined as a comparative quantity that of a solid radiating Surface amount of heat dissipated, with certain other conditions, for example for the difference between the temperature of the metal and the cooling air will. In the present embodiment, the heat exchanger parts are ~ 12 of the last two rows 29f and 29g made of copper, which has a relatively strong heat dissipation enables; the other heat exchanger parts are made of aluminum that absorbs the heat can discharge less intensely.

A specific embodiment of the present invention has been illustrated and described, but various modifications are possible within the scope of the invention.

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Claims (9)

P a t e n t a n s p r ü c h e Electronic device, characterized in that that a chassis (io) with two open, an inlet (17) and an outlet (18) Ends and several heat exchanger parts (12) are provided that each heat exchanger (12) consists of a single piece of sheet metal of uniform thickness and one part of the chassis (10) covering the bottom surface (25) and several elongated, from the bottom portion (25) outgoing, finger-like extensions (26) comprises that several electrical, together connected components each on the bottom surface (25) of a heat exchanger part (12) attached and surrounded by the finger-like extensions (26) that the Extensions (26) of different heat exchanger parts (1 2) have different lengths and are arranged in a certain way to have a passage (13) between them for To create cooling air, which extends from the inlet opening (17) to the outlet opening (18) extends so that the passage (13) has a first vortex section next to the inlet opening (30), whose cross-sectional area increases with increasing distance from the inlet opening (17) that a manifold section (31) in the middle between the inlet opening decreases and the outlet opening is provided in which the passage (13) has the largest cross-sectional area has, and that a second swirl section (32) next to the outlet opening (18) is attached, wherein the effective cross-sectional area of the second swirl portion (32) decreases with increasing distance from the outlet opening (18). 2. Apparatus according to claim 1, characterized in that the finger-like Extensions (26) of each heat exchanger part (12) are parallel and of unequal length. 3. Apparatus according to claim 1, characterized in that the second Vortex section (32) of the passage (13) has the smallest effective cross-sectional area having. 4. Apparatus according to claim 1, characterized in that the effective Cross-sectional area of the first swirl section (30) at its end next to the distributor section (31) larger than the effective cross-sectional area of the second Swirl section (32) at its end next to the outlet opening (18;). 5. Apparatus according to claim 1, characterized in that the finger-like Appendages (26) of each Wáreluauscnerteil (12) arranged in pairs are, and that the finger-like extensions (26) of each pair at the ends of the bottom portion (25) each smaller spacing than the finger-like projections in the middle part of the Have bottom portion (25). 6. The device according to claim 1, characterized in that some the heat exchanger parts are made from a first metal and the remainder of the heat exchanger parts are made from a second metal. 7e device according to claim 6, characterized in that the first Metal is aluminum and the second metal is copper, and that the heat exchanger parts (12) form at least part of the second swirl section (32) made of copper. 8. Apparatus according to claim 6, characterized in that the heat exchanger parts (12) have radiating sections from the second metal which are longer than the radiating portions of the heat exchangers (12) are made of the first metal. 9. Electronic device, characterized in that a chassis (io) with two parallel walls and opposite inner surfaces as well as with two open ends forming an inlet opening (17) and an outlet opening (18) it is provided that several heat exchanger parts are provided, each of which a bottom surface (25) attached to one of the side walls has that several heat radiating parts are attached to the bottom portion (25) and extend away from the walls (15, 16) that some of the heat exchanger parts (12) are made from a first metal and some others are made from a second metal are that the second metal has a stronger heat dissipation than the first metal, that the heat exchanger parts made of the second metal close to the outlet opening (18) are attached that several heat generating components (14) each on the bottom section (25) of one of the heat exchanger parts between the radiating Sections are mounted, and that the radiating sections of different lengths are and are arranged in a certain way so that there is a passage (13) for cooling air with changing cross-sectional area resulting from the chassis (io) of the inlet opening (17) to the outlet opening (18) and the turbulence in the cooling air promotes.