DE20111474U1 - Fan assembly for a cooling device - Google Patents

Description

MÜLLER & HOFFMANN - PATENT ATTORNEYS

European Patent Attorneys - European Trademark Attorneys

Innere Wiener Strasse 17 D-81667 Munich

Attorney file: 53,565

Ho/My/kv 11.07.2001

Truma Gerätetechnik GmbH & Co.

Wernher-von-Braun-Str.

D-85640 Putzbrunn

Fan arrangement for a cooling device

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Truma Gerätetechnik GmbH & Co. 53.565 11.07.2001

Description

The invention relates to a fan arrangement for a cooling device for cooling a room according to the preamble of claim 1.

Cooling devices or air conditioning systems of the type mentioned above are particularly suitable for cooling the interior of caravans, boats or other small spaces. The principle underlying the cooling device of generating cold using a cooling circuit has been known for a long time.

Fig. 3 shows the functional diagram of a well-known cooling circuit or refrigeration process, as used in numerous air conditioning systems.

A compressor 1 compresses a gaseous refrigerant and transports it via a refrigerant line 2 to a condenser 3. The condenser 3, which serves as a heat exchanger, is cooled by ambient air, which is sucked in via an ambient air inlet 5 by means of a condenser fan 4 and blown out via an ambient air outlet 6. This liquefies the initially gaseous refrigerant, which is under high pressure. The liquid refrigerant, which is still under high pressure, is led via a refrigerant line 7 to an expansion device, e.g. a throttle 8, where the refrigerant can expand.

The expansion reduces the temperature of the coolant to below the temperature of the air in the room to be cooled. The coolant is then passed through an evaporator 9, which serves as a heat exchanger and through which the air in the room to be cooled is also passed by means of an evaporator fan 10. In the evaporator 9, the coolant is heated by the air in the room to be cooled, passes into the gaseous phase and thus extracts heat from the air to be cooled. The room air is sucked in through a room air inlet 11 by means of the evaporator fan 10, passed through the evaporator 9 and blown back into the room to be cooled as cold air via one or more room air outlets 12. The room air can be cleaned by a filter 13 before the evaporator 9.

The gaseous refrigerant, heated by the room air to be cooled, is conveyed via a refrigerant line 14 back to the compressor 1. There the

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Truma Gerätetechnik GmbH & Co. 53.565 11.07.2001

gaseous refrigerant is compressed again and the cooling cycle is continued in the manner described above.

One problem with operating a cooling device of the type described above is that, if the ambient air temperature is high, overheating can easily occur in the motor of the condenser fan 4. In addition, the already hot ambient air is heated even further by the waste heat from the motor. The result is failure of the cooling device due to the motor being switched off by a thermal switch. To prevent such incidents, it is usual to use a motor with disproportionately high power for the condenser fan 4, since as the motor power increases, the temperature sensitivity of the motor usually also decreases and the heat can be dissipated better. However, this means that an expensive, large and heavy motor has to be accepted.
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The invention is based on the object of specifying a fan arrangement which can be used in the cooling device described above and which enables a higher temperature insensitivity of the cooling device at the same or lower costs.

According to the invention, the object is achieved by a fan arrangement for a cooling device with the features of claim 1. Advantageous further developments of the invention can be found in the dependent claims.

A central aspect of the invention is that the fan arrangement is designed such that a fan chamber of the condenser fan and a fan chamber of the evaporator fan adjoin one another at a common partition wall. For this purpose, the condenser fan and the evaporator fan can advantageously be combined into one unit.

The advantage of this is that the condenser fan, in particular the condenser fan motor, which has a higher temperature than the evaporator fan, is cooled directly by the cold air flowing in the evaporator fan via the partition wall, since the condenser fan motor sits directly on the partition wall, so that heat conduction between the condenser fan motor and the partition wall is possible. This means that with minimal

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Truma Gerätetechnik GmbH & Co. 53.565 11.07.2001

Temperature peaks in the condenser blower motor can be "defused" with little technical effort in the form of the common partition. The evaporator blower and the common partition thus cool the condenser blower or the condenser blower motor. This makes it possible to use a more temperature-sensitive or less powerful motor. The partition is advantageously made of a material that conducts heat well, for example metal.

In order to keep the cooling effect as great as possible, the suction directions of the condenser fan and the evaporator fan are preferably opposite one another, so that when the fan arrangement is in operation, an intake air flow of the condenser fan is directed to a first side of the partition wall and an intake air flow of the evaporator fan is directed to a second side of the partition wall opposite the first side of the partition wall. The evaporator fan should therefore preferably be designed in such a way that a cold air flow is guided along the partition wall for as long as possible after flowing through the evaporator. The measures described above ensure that an effective heat exchange takes place between the condenser fan and the evaporator fan. Accordingly, the condenser fan motor should be mounted in the condenser fan in such a way that the cold air flow can effectively cool the condenser fan motor through the partition wall.

For this purpose, the condenser blower motor and the evaporator blower motor are preferably each attached directly to the partition wall, with the condenser blower motor being attached to the first side of the partition wall and the evaporator blower motor being attached to the second side of the partition wall opposite the first side. By attaching two motors to a common partition wall, a high degree of stiffening of the partition wall can also be achieved, which leads to a high degree of stability of the blower arrangement.

If the motor rotation axes of the condenser blower motor and the evaporator blower motor are arranged parallel and offset from each other and the distance between the motor rotation axes is such that the axial projections of the two motors, including the motor housings, overlap, an extremely compact design of the blower arrangement can be achieved, which also enables the advantages of an effective heat exchange described above. The weight saving that can be achieved through the common partition wall also

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Truma Gerätetechnik GmbH & Co. 53.565 11.07.2001

compared to a solution with two separate supporting walls for the fan motors is not insignificant.

These and other advantages and features of the invention are explained in more detail below with the aid of the accompanying figures.

Show it:

Fig. 1 is a schematic plan view of a blower according to the invention.

arrangement, which is integrated into a suitable cooling device

is grated; and

Fig. 2 is an exploded perspective view of the blower assembly according to the invention;
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Fig. 3 shows the previously described functional diagram of a cooling circuit.

In the drawings, corresponding components are marked with the same reference symbols.

Fig. 1 shows a cooling device with a compressor 1, a first refrigerant line 2, a condenser 3, a condenser fan 4, an ambient air inlet 5, a second refrigerant line 7, a third refrigerant line 7a, a throttle 8, an evaporator 9, an evaporator fan 10, a room air inlet 11, a room air outlet 12, a filter 13, a fourth refrigerant line 14, a common partition wall 15 with a first side 16 and a second side 17, a condenser fan motor 18, an evaporator fan motor 19, a carrier 20, a main direction 21, a first flow space 22, a second flow space 23 and a third flow space 24.

In this example, the fan arrangement according to the invention consists of the condenser fan 4, the evaporator fan 10, the first flow chamber 22 and the second flow chamber 23. However, the first and second flow chambers 22, 23 can also be omitted or integrated into the condenser fan 4 and the evaporator fan 10. The fan arrangement preferably forms a unit so that it can be removed from the cooling device as a whole.

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Truma Gerätetechnik GmbH & Co. 53.565 11.07.2001

The coolant fed to the compressor 1 is compressed by the compressor and fed to the condenser 3 via the first coolant line 2. Ambient air is sucked in through the ambient air inlet 5 by the evaporator fan 4, passed through the condenser 3 and led out again through an ambient air outlet (not shown). This liquefies the coolant in the condenser 3 and is fed to the throttle 8 via the second coolant line 7. After passing through the throttle 8, the coolant expands in the third coolant line 7a. This reduces the pressure and temperature of the coolant. The expanded coolant flows through the evaporator 9, where it changes to the gaseous state. In the process, heat is extracted from an air flow that is sucked in from a room to be cooled through the room air inlet 11, the filter 13, the third flow chamber 24, the evaporator 9 and the second flow chamber 23. The air flow sucked through the second flow chamber 23 is fed back to the room to be cooled by the evaporator fan 10 and via the room air outlets 12. The heated, gaseous refrigerant is fed to the compressor 1 via the fourth refrigerant line 14 and the cooling cycle begins again.

The condenser fan motor 18 is attached to the first side 16 of the partition wall 15, whereas the evaporator fan motor 19 is attached to the second side 17 of the partition wall 15. This achieves a high rigidity of the partition wall 15, which increases the stability of the fan arrangement.

The motor rotation axes of the condenser blower motor 18 and the evaporator blower motor 19 are arranged parallel to one another and offset from one another, with the motor rotation axes 25, 26 being spaced apart from one another in such a way that axial projections of the two motors 18, 19 including the corresponding motor housings overlap with one another. This enables an extremely compact, modular design of the blower arrangement according to the invention.
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The arrangement described above ensures that the suction directions of the condenser fan 4 and the evaporator fan 10 are aligned parallel to a main direction 21, wherein the suction direction of the condenser fan motor 18 corresponds to the main direction 21, while the suction direction of the evaporator fan 10 is aligned parallel to the main direction 21, but is opposite to it.

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Truma Gerätetechnik GmbH & Co. 53.565 11.07.2001

As a result, an intake air flow from the evaporator fan 10 hits the second side 17 of the partition wall 15. The intake air flow, cooled after passing through the evaporator 9, is guided along the second side 17 in order to reach the room air outlets 12, thereby cooling the partition wall 15.

The condenser fan motor 18 rests on the partition wall 15 and is therefore in good thermal contact with it. The cooling of the partition wall 15 can therefore also effectively cool the condenser fan motor 18, which has a much higher temperature than the evaporator fan 19. As a result, overheating of the condenser fan motor 18 can be prevented, particularly if the common partition wall 15 is made of a material that conducts heat well.

The common partition wall 15 also saves material and weight.

As can be seen from Fig. 1, the evaporator fan 10 and the room air outlets 12 are offset from one another in such a way that the intake air flow cooled by the evaporator 9 is guided along the second side 17 of the common partition wall 15 for as long as possible, whereby a good cooling effect of the condenser fan motor 18 attached to the rear can be achieved.

Fig. 2 shows an exploded view of an embodiment of the fan arrangement according to the invention, which essentially corresponds to that of Fig. 1. For reasons of clarity, the partition wall 15 is shown twice, namely once as a support for the condenser fan motor 18 and once as a support for the evaporator fan motor 19. In fact, however, the partition wall 15 only exists once and carries both fan motors 18, 19. In this embodiment, the first flow space 22 is integrated into the housing of the condenser fan 4, and the second flow space 23 is integrated into the housing of the evaporator fan 10. Furthermore, Fig. 2 shows the already mentioned ambient air outlet 6, which is arranged on the underside of the condenser fan 4, a motor axis 26 of the condenser fan motor 18 and a motor axis 25 of the evaporator fan motor 19. The motors are arranged parallel and offset from one another.

Claims (8)

1. Fan arrangement for a cooling device for cooling a room, the cooling device having a cooling circuit with: - a compressor ( 1 ) for compressing a refrigerant, - a condenser ( 3 ) with an associated condenser fan ( 4 ) for supplying and removing ambient air, - an expansion device ( 8 ) for expanding the refrigerant, and - an evaporator ( 9 ) with an associated evaporator fan ( 10 ) for supplying and removing room air from the room to be cooled, characterized in that
a blower chamber of the condenser blower ( 4 ) and a blower chamber of the evaporator blower ( 10 ) adjoin one another at a common partition wall ( 15 ). 2. Blower arrangement according to claim 1, characterized in that the condenser blower ( 4 ) and the evaporator blower ( 10 ) are combined to form a unit. 3. Blower arrangement according to claim 1 or 2, characterized in that the partition wall ( 15 ) consists of a material with good heat conduction. 4. Blower arrangement according to claim 1 or 2, characterized in that a condenser blower motor ( 18 ) and an evaporator blower motor ( 19 ) are each fastened directly to the partition wall ( 15 ), the condenser blower motor ( 18 ) being fastened to a first side (16) of the partition wall ( 15 ), and the evaporator blower motor ( 19 ) being fastened to a second side (17) of the partition wall ( 15 ) opposite the first side. 5. Blower arrangement according to claim 4, characterized in that the motor rotation axes ( 25 , 26 ) of the condenser blower motor ( 18 ) and the evaporator blower motor ( 19 ) are arranged parallel and offset from one another. 6. Blower arrangement according to claim 5, characterized in that the distance between the motor rotation axes ( 25 , 26 ) is dimensioned such that axial projections of the two motors ( 18 , 19 ) including the motor housings overlap with one another. 7. Blower arrangement according to one of the preceding claims, characterized in that the suction directions of the condenser blower ( 4 ) and the evaporator blower ( 10 ) are opposite to one another, so that when the blower arrangement is in operation, an intake air flow of the condenser blower ( 4 ) can be directed to the first side (16) of the partition wall ( 15 ), and an intake air flow of the evaporator blower ( 10 ) can be directed to the second side (17) of the partition wall ( 15 ) opposite the first side (16) of the partition wall ( 15 ). 8. Blower arrangement according to one of the preceding claims, characterized in that the evaporator blower ( 10 ) is designed such that a cold air flow is guided along the partition wall ( 15 ) after flowing through the evaporator ( 9 ).