EP3184935A1 - Cooling device having a peltier element - Google Patents

Abstract

The invention relates to a cooling device (200) comprising: a cold exchanger (203) for cooling air in an air space; a Peltier element (210) configured to cool the refrigerant exchanger (203); and an air compressor (205) configured to draw air from the air space, to compress the sucked air to obtain compressed air heated by compression, the air compressor (205) being further configured to communicate the refrigerant exchanger (203) with the compressed one Apply air to heat the exchanger (203).

Description

The present invention relates to a cooling device with Peltier element, a cooling method and a control cabinet with such a cooling device.

Cabinets in high ambient temperature (> 55 ° C) environments often have major cooling issues, especially with systems installed on moving systems. Cooling using conventional air conditioning is no longer effective, as the maximum ambient temperature of these units is exceeded and, with passive cooling, the air in the interior of the control cabinet may reach a higher temperature than the ambient air outside the control cabinet.

On moving systems, there is also the problem of acceleration forces or vibrations. Peltier coolers are very well suited for this area. However, this results in the problem of too low cooling pipe at a high temperature difference between the inside of the cabinet and ambient air. The components in the control cabinet may in many cases only be exposed to a maximum temperature of 45 ° C, or even 40 ° C. Temperature differences of 15 K and higher are the result. Often many Peltier devices have to be operated simultaneously on a control cabinet in order to achieve the required cooling line, which leads to very high costs. In some cases, cooling by means of Peltier devices is also no longer possible because the required number of coolers exceeds the available surface of the control cabinet.

In "conventional" Peltier coolers cooling takes place as in FIG. 1a shown, ie it is the warm cabinet interior air 12 sucked through a fan 11 and passed over the cold surface of the refrigerant exchanger (fin heat sink) and thus cooled 13. The cooled air 14 then flows directly back into the cabinet. The problem here is that at high temperature difference between the indoor air and ambient air of the cabinet, which consequently leads to high temperature difference between the refrigerant and heat exchanger to a low cooling capacity of the Peltier modules.

It is the object of the present invention to provide a concept for a suitable cooling of control cabinets, which reliably cools the control cabinet in the scenarios described above.

This object is solved by the features of the independent claims. Advantageous forms of further education are the subject of the dependent claims.

The cooling device described below comprises one or more Peltier elements or Peltier modules based on the Peltier effect. The Peltier effect causes a generation of a temperature difference by an electric current flow. For this purpose, two different metals or n- and p-doped semiconductor crystals can be used. If direct current is sent through the Peltier element, the copper bridge, which connects the two metals or semiconductors on one upper side, cools down. The two, also made of copper connecting bridges on the bottom of the Peltier element heat up against it. Thus, a steady heat transfer takes place from the upper copper bridge to the lower copper bridges. In a Peltier module, many of these Peltier elements are electrically connected in series and thermally connected in parallel, creating a hot and a cold surface. These Peltier modules in turn can now be electrically connected in series or parallel, if large cooling surfaces are needed.

The principle of Peltier cooling corresponds to that of an electric heat pump. The Peltier elements transport the heat energy from the refrigeration exchanger inside the control cabinet to the heat exchanger on the outside of the control cabinet. The warm air inside the cabinet is blown by a fan on the refrigerant exchanger and thereby cooled. The heat exchanger on the outside of the control cabinet is then cooled with ambient air. The advantage of Peltier cooling is above all the functional safety. There are no liquids and therefore no danger of leaks. In addition, Peltier coolers can therefore also be used on moving or accelerated systems.

According to a first aspect, the invention relates to a cooling device comprising: a refrigerant exchanger for cooling air in an air space; a Peltier element configured to cool the refrigerant exchanger; and an air compressor, which is designed to suck in air from the air space, to compress the intake air, to obtain compressed air heated by compression, wherein the air compressor is further configured to pressurize the refrigerant exchanger with the compressed air to heat the refrigerant exchanger.

This has the advantage that the cooling of the air in the compressed and heated state causes a significant increase in the cooling capacity of the Peltier modules, since the temperature difference is much cheaper. Compression and the release of air can adiabatically add up to zero. Due to the pre-compression, the cooling device also reliably cools control cabinets in the above-described scenarios of high temperature difference between the refrigeration exchanger and heat exchanger, in which, for example, the ambient air is hotter than the interior of the control cabinet.

According to one embodiment of the cooling device, the cooling exchanger has an air inlet, an air outlet and an air duct, furthermore, the air duct has an air duct inlet fluidically connected to the air inlet and an air duct outlet fluidically connected to the air outlet, and the compressor is formed, the compressed air being the air duct supplied via the air duct inlet, further, the air duct is flowed through by the compressed air to heat the refrigerant exchanger, and further the compressed air via the air duct outlet can flow out.

This has the advantage that between the air inlet and air outlet, a continuously cooled air flow can be generated, which causes a continuous cooling of the control cabinet.

According to an embodiment of the cooling device, the air outlet is aligned with the air space to relax the compressed air in the air space again.

This has the advantage that the cooled air flows back into the air space, so as to cool the cabinet interior.

According to one embodiment of the cooling device, the air duct inlet and the air duct outlet are each arranged laterally of the air duct, furthermore, the air duct inlet is laterally in each case by a first sealing part, in particular a Furthermore, in the first sealing part, a first air opening is formed, further in the second sealing part, a second air opening is formed, further, the first air opening is associated with the air inlet, and the second Air opening is assigned to the air outlet.

This has the advantage that a continuous flow of air can be generated with high efficiency. The sealing members cause the air to pass through the air duct only through the air inlet and exit through the air outlet without escaping elsewhere.

According to an embodiment of the cooling device, the air duct inlet is arranged on a first end side of the air duct, further the air duct outlet is arranged on a second end side of the air duct, further sealing the first sealing member from the first end side, further seals the second sealing member from the second end face, and between the respective sealing member and the respective end face a circumferential air seal is arranged in each case.

This has the advantage that the air duct is formed as tight as possible and thus has a high efficiency.

According to one embodiment of the cooling device, the cold exchanger has a mounting plate which is designed for mounting the air compressor. Furthermore, the air duct is connected to the mounting plate. Further, the mounting plate has a first opening, which is associated with the air inlet, and the mounting plate has a second opening, which is associated with the air outlet.

This has the advantage that the mounting plate provides a simple mounting option for the air compressor. The mounting plate can be made of metal or plastic.

According to one embodiment of the cooling device, the cooling device is designed to deliver the compressed air after the heating of the refrigerant exchanger to the air space, in particular to deliver relaxed.

This has the advantage that the air is only relaxed after the Peltier element and thus cooled, so that the Peltier element can work with the compressed and heated air. This increases the cooling capacity of the Peltier element, as the temperature difference is significantly more favorable.

According to one embodiment of the cooling device, the air compressor is arranged on a side of the refrigerant exchanger facing the air space.

This has the advantage that the air compressor is located inside the cabinet where it can be easily powered.

According to one embodiment, the cooling device is provided for cooling a control cabinet, wherein the air compressor is arranged on an outer side of the control cabinet.

This has the advantage that in the design of the cabinet no space must be kept to accommodate the air compressor.

According to one embodiment of the cooling device, the cooling device further comprises a heat exchanger for cooling the Peltier element.

This has the advantage that the cooling performance of the Peltier elements increases when they are cooled by the heat exchanger.

According to one embodiment of the cooling device, the Peltier element is thermally conductively connected to the cold exchanger.

This has the advantage that the cooling energy generated by the Peltier elements can be delivered as efficiently as possible via the refrigerant exchanger to the control cabinet.

According to one embodiment, the cooling device is accommodated in a sidetable device to a control cabinet.

This has the advantage that the Beistellgerät with the cooling device is flexible and can be used for various cabinets.

According to one embodiment of the cooling device, the auxiliary device has hoses which are designed to transport the air drawn in from the air space and the air returned into the air space.

This has the advantage that the additional device can be flexibly and quickly connected to the control cabinet through the hoses. Further, the sizing device may have a different size, depending on how many cooling devices are to be accommodated therein or a flexible number of sidetables may be connected to the control cabinet depending on the cooling requirements.

In a second aspect, the invention relates to a cooling method comprising the steps of: drawing air from an air space; Compressing the sucked air to obtain compressed air heated by compression; Cooling the heated compressed air with a refrigerant exchanger cooled by a Peltier element; and relaxing the compressed air in the air space after cooling with the refrigerant exchanger.

This has the advantage that with the cooling of the air in the compressed and heated state, a significant increase in the cooling capacity of the Peltier element can be effected, since the temperature difference is much cheaper. Compression and relaxation of the air can adiabatically add up to zero. Due to precompression, efficient and reliable cooling can also be achieved in the high temperature difference scenarios described above.

According to a third aspect, the invention relates to a control cabinet for housing at least one electrical component, wherein the control cabinet has a control cabinet interior, which encloses an air space,
wherein in a breakthrough of a Schaltungskwandung the cooling device is arranged according to the first aspect described above or one of its embodiments for cooling the air space, wherein the air compressor is adapted to suck air from the air space to compress the sucked air to by compression heated compressed air, wherein the air compressor is further configured to pressurize the refrigerant exchanger with the compressed air to heat the refrigerant exchanger, and wherein the cooling device is adapted to deliver the compressed air after heating of the refrigerant exchanger to the air space to the to relax compressed air again.

This has the advantage that a control cabinet with such a cooling device can be cooled particularly efficiently and reliably. A continuous air circulation is generated, which continuously cools the cabinet interior.

• Fig. 1a eine schematische Darstellung eines herkömmlichen Kühlverfahrens 10;
• Fig. 1b eine schematische Darstellung eines erfindungsgemäßen Kühlverfahrens 100;
• Fig. 2a: eine dreidimensionale Darstellung einer erfindungsgemäßen Kühlvorrichtung 200 in Seitenansicht mit Blick auf die Schaltschrankinnenseite;
• Fig. 2b: eine dreidimensionale Darstellung der erfindungsgemäßen Kühlvorrichtung 200 in Draufsicht mit Blick auf die Schaltschrankaußenseite;
• Fig. 2c: eine Explosionsdarstellung der erfindungsgemäßen Kühlvorrichtung 200 mit einzelnen Komponenten; und
• Fig. 3: ein Leistungsdiagramm 300 eines Peltier-Moduls 210 bei verschiedenen Temperaturdifferenzen zwischen Kälte- und Wärmetauscher.

Further embodiments will be explained with reference to the accompanying drawings. Show it:

• Fig. 1a a schematic representation of a conventional cooling method 10;
• Fig. 1b a schematic representation of a cooling method 100 according to the invention;
• Fig. 2a a three-dimensional representation of a cooling device 200 according to the invention in a side view with a view of the cabinet inside;
• Fig. 2b a three-dimensional representation of the cooling device 200 according to the invention in a plan view with a view of the outside of the control cabinet;
• Fig. 2c an exploded view of the cooling device 200 according to the invention with individual components; and
• Fig. 3 a power diagram 300 of a Peltier module 210 at different temperature differences between the refrigerant and heat exchanger.

In the following detailed description, reference is made to the accompanying drawings, which form a part hereof, and in which is shown by way of illustration specific embodiments in which the invention may be practiced. It is understood that other embodiments are utilized and structural or making logical changes without departing from the concept of the present invention. The following detailed description is therefore not to be understood in a limiting sense. Further, it should be understood that the features of the various embodiments described herein may be combined with each other unless specifically stated otherwise.

Aspects and embodiments will be described with reference to the drawings, wherein like reference numerals generally refer to like elements. In the following description, for purposes of explanation, numerous specific details are set forth in order to provide a thorough understanding of one or more aspects of the invention. However, it will be apparent to one skilled in the art that one or more aspects or embodiments may be practiced with a lesser degree of specific details. In other instances, well-known structures and elements are shown in schematic form to facilitate describing one or more aspects or embodiments. It is understood that other embodiments may be utilized and structural or logical changes may be made without departing from the concept of the present invention.

Furthermore, while a particular feature or aspect of an embodiment may have been disclosed in terms of only one of several implementations, such feature or aspect may be combined with one or more other features or aspects of the other implementations, as for a given or particular one Application may be desirable and advantageous. Furthermore, to the extent that the terms "contain,""have,""with," or other variants thereof are used in either the detailed description or the claims, such terms are intended to include such terms in a manner similar to the term "comprising." The terms "coupled" and "connected" may have been used along with derivatives thereof. It should be understood that such terms are used to indicate that two elements independently cooperate or interact with each other, whether they are in direct physical or electrical contact or are not in direct contact with each other. In addition, the term "exemplary" is to be considered as an example only instead of the name for the best or optimal. The following description is therefore not to be understood in a limiting sense.

Fig. 1b shows a schematic representation of a cooling method 100 according to the invention. The cooling method 100 comprises the following steps: suction 101 of air 102 from an air space, eg in a control cabinet interior; Compressing 103 the sucked air to obtain compressed air heated by compression; Cooling the heated compressed air with a cold exchanger cooled by a Peltier element; and relaxing 107 of the compressed air in the air space, for example, back into the cabinet interior after cooling 105 with the refrigerant exchanger.

For example, the warm air from the cabinet interior may have a temperature of e.g. 40 degrees Celsius and are under a pressure of 1 bar. The compression 103 may compress the air so that, for example, it is under pressure of 7 bar after compression 103 and has a temperature of e.g. 90 degrees Celsius. The cooling 105 can be applied to this compressed heated air. After relaxing 107, the air may again be heated at a temperature of e.g. 40 degrees Celsius and a pressure of e.g. 1 bar are returned to the air space or the cabinet interior, so that the cooling method 100 causes the cabinet air to remain at an approximately constant temperature of 40 degrees Celsius.

It is understood that the temperature values and pressure values mentioned here are only exemplary values. Other parameters for temperature and pressure may also be used, for example T = 30, 35, 45, 50, 55 degrees C and p = 0.5, 1.5, 2 bar on intake 101; for example T = 50, 55, 60, 65, 70, 75, 80, 85, 95, 100, 105, 110, 115, 120 degrees C and p = 3, 3.5, 4, 4.5, 5, 5.5, 6, 6.5 , 7, 7.5, 8.5, 9, 9.5, 10, 10.5, 11 bar after compaction 103; and, for example T = 30, 35, 45, 50, 55 degrees C and p = 0.5, 1.5, 2 bar after relaxing 107. Further, after relaxing 107, a temperature difference between the expanded air 104 and sucked air 102 remain.

This in FIG. 1b illustrated method 100 can be used in systems of the invention, which are also referred to as "pre-compression systems" hereinafter. In these pre-compression systems, the inside of the enclosure is sucked in, through compressed and heated a compressor, cooled by means of Peltier modules and then relieved back into the control cabinet. The compression and the relaxation add up adiabatically to zero. The cooling of the air in the compressed and heated state causes a significant increase in the cooling capacity of the Peltier modules, since the temperature difference is much cheaper.

By reducing the temperature difference between the refrigerant and heat exchangers, an increase in cooling capacity of approximately 300% can be achieved. Thus, the cooling method 100 according to the invention can achieve a high cooling capacity with a high temperature difference. Cooling devices and Peltier cooling devices based on such a method 100 are described below.

Fig. 2a shows a three-dimensional view of a cooling device 200 according to the invention in side view overlooking the cabinet inside.

The cooling device 200 comprises a cold exchanger 203 for cooling air in an air space, e.g. in a cabinet interior; a Peltier element 210, with which the refrigerant exchanger 203 is cooled and an air compressor 205 or compressor.

The Peltier element 210 is in FIG. 2a not visible because it is located within the seal 202 between the exchanger 203 and heat exchanger 201, in the exploded view of Figure 2c However, the Peltier element is shown.

The air compressor 205 serves to suck in air from the air space and to compress, so as to obtain by compression heated compressed air. The air compressor 205 also serves to pressurize the refrigerant exchanger 203 with the compressed air so as to heat the refrigerant exchanger 203.

The air compressor 205 is disposed on an airspace side of the refrigerant exchanger 203, as shown in FIG FIG. 2a is apparent.

The cooling device 200 further includes a heat exchanger 201 for cooling the Peltier element 210. The Peltier element 210 is connected in a heat-conducting manner to the cold exchanger 203.

Furthermore, in FIG. 2a a power supply 208 is shown that powers the Peltier elements that require DC power. The compressor 205 runs in the present embodiment with 230V AC voltage available from the grid. Alternatively, a DC compressor may be used, which may then be powered by the power supply 208.

The cooling device 200 is provided for cooling a cabinet interior. The cold exchanger 203 may be facing the cabinet interior, which includes the above airspace. The cooling device 200 may be mounted to the cabinet such that the outer hood 204 and the heat exchanger 201 are outside the cabinet and the remaining components, i. Refrigeration exchanger 203 with Peltier elements and compressor 205 are located in the interior of the control cabinet. For airtight attachment of the cooling device 200 to the control cabinet, the cooling device 200 has a seal 202 to the control cabinet wall. The seal 202 also serves to dampen vibrations due to the operation of the compressor 205 and to decouple from the cabinet.

Such a cabinet may be provided for housing one or more electrical components. The cabinet may have a cabinet interior that includes an air space as described above. In a breakthrough of a cabinet wall, the cooling device 200 may be arranged for cooling the air space. The air compressor 205 serves to suck in air from the air space, to compress the sucked air so as to obtain compressed air heated by compression. The air compressor 205 may apply the compressed air to the refrigerant exchanger 203 so as to heat the refrigerant exchanger 203. The cooling device 200 serves to deliver the compressed air after the heating of the refrigerant exchanger 203 to the air space in order to relax the compressed air again.

The cooling device 200 can also be used at an ambient temperature of more than 70 ° C. The cooling device 200 is designed so that it can be operated with always the same supply voltage. The achievable temperature difference between indoor and outdoor air is mainly dependent on the power loss of the electrical components in the cabinet.

Alternatively, the cooling device 200 may be housed in a Beistellgerät to a control cabinet. For this purpose, the auxiliary device may have hoses for transporting the air taken in from the air space and the air returned into the air space from the air space inside the control cabinet to the cooling device 200 in the auxiliary device and back.

Fig. 2b shows a three-dimensional representation of the cooling device 200 according to the invention in plan view with a view of the outside of the cabinet.

In the plan view, fan slots 211 are additionally visible in a main area of the outer hood 204, below which fans are located in order to improve the heat removal of the warm air from the heat exchanger 201 to the environment.

Fig. 2c shows an exploded view of the cooling device 200 according to the invention with individual components.

As above FIG. 2a already shown, the cooling device 200 comprises a cold exchanger 203 for cooling air in an air space, for example in a cabinet interior; a Peltier element 210, with which the refrigerant exchanger 203 is cooled and an air compressor 205 or compressor.

The Peltier element may be implemented as an entire array of individual Peltier elements to provide a better cooling line.

The air compressor 205 serves to suck in air from the air space and to compress, so as to obtain by compression heated compressed air. The air compressor 205 also serves to pressurize the refrigerant exchanger 203 with the compressed air so as to heat the refrigerant exchanger 203.

The refrigerant exchanger 203 has an air inlet 207, an air outlet 206, as in FIG FIG. 2a described, and an air duct (inside the refrigerant exchanger realized, not visible in Figure 2c ) on. The air duct has an air duct inlet 212a fluidically connected to the air inlet 207 and an air duct outlet 212b fluidically connected to the air outlet 206. Air channel inlet 212a and air channel exit 212b may be realized as separate parts that can be laterally attached to the cold exchanger 203, as in FIG Figure 2c shown in more detail.

The compressor 205 serves to supply the compressed air to the air duct via the air duct inlet 212a. The air duct can be traversed by the compressed air, i. the compressed air can flow through the air duct so as to heat the refrigerant exchanger 203. The compressed air can be flowed out via the air duct outlet 212b, i. it can flow out via the air duct outlet 212b.

The air outlet 206 is aligned with the air space so as to relax the compressed air in the air space again.

The air duct inlet 212a and the air duct outlet 212b are each disposed laterally of the air duct, as in the exploded view of Figure 2c can be seen. The air duct inlet 212a is laterally sealed by a first sealing part 213a, for example a plastic sealing part, and the air duct outlet 212b is laterally sealed by a second sealing part 213b, as in the exploded view of FIG Figure 2c can be seen. In the first sealing part 213a, a first air opening is formed, and in the second sealing part 213b, a second air opening is formed, as in FIG Figure 2c is recognizable. The first air opening is assigned to the air inlet 207 and the second air opening is assigned to the air outlet 206.

The air duct inlet 212a is disposed at a first end face of the air duct, and the air duct outlet 212b is disposed at a second end side of the air duct as shown in FIG Figure 2c shown. The first sealing part 213a seals off the first end side and the second sealing part 213b seals off the second end side, as in FIG Figure 2c you can see. Between the respective sealing part 213a, 213b and the respective end face, in each case a circumferential air seal can be arranged.

The refrigerant exchanger 203 has a mounting plate 215, as in the exploded view of Figure 2c shown. The mounting plate 215 has a first opening 215a, as in FIG Figure 2c to see which is associated with the air inlet 207. The mounting plate 215 further includes a second aperture 215b, also in FIG Figure 2c can be seen, which is associated with the air outlet 206. In the above described FIG. 2a first aperture 215a and second aperture 215b are mounted within the housing of the refrigerant exchanger 203 below the two openings for air inlet 207 and air outlet 206 in the non-visible mounting plate 215 on which the compressor 205 is mounted.

The cooling device 200 discharges the compressed air after heating the refrigerant exchanger 203 to the air space. In particular, the cooling device releases the compressed air in the relaxed state again.

The air inlet 207 and the air outlet 206 each have a pipe socket 214a, 214b, which are fluidically connected to the air compressor 205. That is, in the operating state of the cooling device 200, a continuous air flow flows through the pipe socket 214a at the air inlet 207 in the air compressor 205, is compressed there, and flows through the pipe socket 214b at the air outlet 206 from the air compressor 205 out where the air flow is relaxed again , The pipe socket 214b at the air outlet 206 thus serves as a throttle to relax the air stream compressed in the compressor 205 again.

A second seal 216 is mounted on the conductive plate 215 together with the air compressor 205. The second seal 216 has an opening through which the air compressor 205 is directly contacted with the conductive plate 215. Positions of the conductive plate which are not in contact with the air compressor 205 are covered by the second gasket 216. The second seal 216 comprises two openings or holes 216a, 216b, which are aligned with respect to the first opening 215a and the second opening 215b of the conductive plate 215, so that the two raw nozzles 214a, 214b penetrate into the respective opening in the conductive plate and corresponding opening of the second seal can be introduced.

Fig. 3 shows a performance diagram 300 of a Peltier module 210 at different temperature differences between the refrigerant and heat exchanger.

The Peltier module 210 is part of the above to FIG. 2 A first curve 301 shows the performance of the Peltier module 210 at a temperature difference of 25% Imax (maximum current), a second curve 302 shows the performance of the Peltier module 210 at a temperature difference of 50% Imax, a third one Curve 303 shows the performance of Peltier module 210 at a temperature difference of 75% Imax and a fourth graph 304 shows the performance of Peltier module 210 at a temperature difference of 100% Imax.

It is to be understood that the features of the various embodiments described herein by way of example may be combined with each other except as specifically stated otherwise. As shown in the specification and drawings, individual elements that have been shown to be related need not communicate directly with each other; Intermediate elements may be provided between the connected elements. The term "for example" is meant as an example only and not as the best or optimal. While particular embodiments have been illustrated and described herein, it will be apparent to those skilled in the art that a variety of alternative and / or similar implementations may be practiced instead of the illustrated and described embodiments without departing from the concept of the present invention.

LIST OF REFERENCE NUMBERS

10:

conventional cooling method

11:

suck in

12:

incoming warm air

13:

cooling

14:

output-side cooled air

100:

Cooling process according to the invention

101:

suck in

102:

incoming warm air

103:

Compression or compression

104:

output-side cooled air

105:

cooling

107:

Relaxation

200:

Cooling device according to the invention

201:

heat exchangers

202:

Seal (to the control cabinet wall)

203:

cold exchanger

204:

exterior hood

205:

Compressor or compressor

206:

Cold air outlet or air outlet

207:

Air intake or air intake

208:

power adapter

209:

Fan

210:

Peltier element

211:

Fan slots or fan openings

212a:

Air channel input

212b:

Air channel output

213a:

first sealing part

213b:

second sealing part

214a:

Pipe socket at the air inlet

214b:

Pipe socket at the air outlet

215:

mounting plate

215a:

first breakthrough in the mounting plate

215b:

second breakthrough in the mounting plate

216:

Seal (to the compressor)

216a:

first opening in the gasket

216b:

second opening in the seal

300:

Performance diagram of a Peltier module

301:

first count, at 25% Imax

302:

second count, at 50% Imax

303:

third count, at 75% Imax

304:

fourth count, at 100% Imax

Claims (15)

Cooling device (200) with: a refrigerant exchanger (203) for cooling air in an air space; a Peltier element (210) configured to cool the refrigerant exchanger (203); and an air compressor (205) configured to draw air from the air space, to compress the sucked air to obtain compressed air heated by compression, the air compressor (205) being further configured to communicate the refrigerant exchanger (203) with the compressed air to apply to heat the refrigerant exchanger (203). Cooling device (200) according to claim 1,
wherein the cold exchanger (203) has an air inlet (207), an air outlet (206) and an air duct,
wherein the air duct has an air duct inlet (212a) fluidly connected to the air inlet (207) and an air duct outlet (212b) fluidly connected to the air outlet (206),
wherein the compressor (205) is configured to supply the compressed air to the air duct via the air duct inlet (212a),
wherein the air duct is flowed through by the compressed air to heat the refrigerant exchanger (203), and
wherein the compressed air via the air duct outlet (212b) can be flowed out. Cooling device (200) according to claim 2,
wherein the air outlet (206) is aligned with the air space to relax the compressed air in the air space again. Cooling device (200) according to claim 2 or 3,
wherein the air duct inlet (212a) and the air duct outlet (212b) are each arranged laterally of the air duct,
the air duct inlet (212a) being sealed laterally in each case by a first sealing part (213a), in particular a plastic sealing part,
the air duct exit (212b) being sealed laterally by a second sealing part (213b),
wherein a first air opening is formed in the first sealing part (213a),
wherein a second air opening is formed in the second sealing part (213b),
wherein the first air opening is associated with the air inlet (207), and
wherein the second air opening is associated with the air outlet (206). Cooling device (200) according to claim 4,
the air duct inlet (212a) being arranged on a first end side of the air duct,
wherein the air duct outlet (212b) is arranged on a second end face of the air duct,
wherein the first sealing member (213a) seals the first end face,
wherein the second sealing member (213b) seals the second end face, and
wherein in each case a circumferential air seal is arranged between the respective sealing part (213a, 213b) and the respective end face. Cooling device (200) according to one of claims 2 to 5,
wherein the cold exchanger (203) has a mounting plate (215), which is designed for mounting the air compressor (205),
wherein the air duct is connected to the mounting plate (215),
wherein the mounting plate (215) has a first aperture (215a) associated with the air inlet (207), and
wherein the mounting plate (215) has a second aperture (215b) associated with the air outlet (206). Cooling device (200) according to one of the preceding claims,
which is designed to deliver the compressed air after the heating of the refrigerant exchanger (203) to the air space, in particular to deliver relaxed. Cooling device (200) according to one of the preceding claims,
wherein the air compressor (205) is disposed on an airspace side of the refrigerant exchanger (203). Cooling device (200) according to one of claims 1 to 7,
which is intended for cooling a control cabinet,
wherein the air compressor (205) is disposed on an outside of the cabinet. Cooling device (200) according to one of the preceding claims,
which further comprises a heat exchanger (201) for cooling the Peltier element (210). Cooling device (200) according to one of the preceding claims,
wherein the Peltier element (210) is thermally conductively connected to the cold exchanger (203). Cooling device (200) according to one of the preceding claims,
which is housed in a Beistellgerät to a control cabinet. Cooling device (200) according to claim 12,
wherein the auxiliary device has hoses which are adapted to transport the air sucked from the air space and the air returned into the air space. Cooling method (100) with the following steps: Aspirating (101) air (102) from an airspace; Compressing (103) the sucked air to obtain compressed air heated by compression; Cooling (105) the heated compressed air with a refrigerant exchanger cooled by a Peltier element; and Relax (107) the compressed air into the air space after cooling (105) with the refrigerant exchanger. Switch cabinet for housing at least one electrical component,
wherein the control cabinet has a cabinet interior, which includes an air space,
wherein in a breakthrough of a switching cabinet wall, the cooling device (200) is arranged according to one of the preceding claims for cooling the air space,
wherein the air compressor (205) is adapted to suck air from the air space, to compress the sucked air to obtain compressed air heated by compression,
wherein the air compressor (205) is further configured to pressurize the refrigerant exchanger (203) with the compressed air to heat the refrigerant exchanger (203), and
wherein the cooling device (200) is designed to deliver the compressed air to the air space after the heating of the cold exchanger (203) in order to relax the compressed air again.

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