DE29613801U1 - Cooling unit - Google Patents

Description

9 August 1996
96-1575 G/Jp-hd

LiebheiT-Werk Lienz Ges.m.b.H., A-9900 Lienz

Cooling device

The invention relates to a cooling device, in particular a deep freezer or an ice cream freezer, with an evaporator, a condenser and a compressor that can be operated with solar power from a photovoltaic system.

Cooling devices of this type are usually operated on the normal power grid. However, in the case of ice cream chests in particular, there are already corresponding devices that are operated with solar energy via photovoltaic systems in order to be able to be independent of the respective power connection for special installation locations, such as in swimming pools, on the beach, etc. One disadvantage of such ice cream chests, however, is that the battery belonging to the photovoltaic system must be designed with a sufficiently large charge capacity in order to be able to bridge longer periods of darkness, which occur particularly during night-time operation. This makes the electrical components of a solar-powered ice cream chest expensive and complex, and the ice cream chest is also very heavy due to the battery that has to be designed accordingly, making it difficult to transport.

The object of the invention is therefore to create a cooling device of the generic type that is easy to transport and can be used flexibly.

This object is achieved by the features set out in claim 1. The solution according to the invention consists in the fact that parallel to the solar power

Compressor, a compressor that can be operated with mains power is installed in the refrigeration system and that the mains power compressor and the solar power compressor are locked against each other in such a way that only the mains power compressor or the solar power compressor can be operated. With two compressors connected in parallel in this way, it is possible to operate a cooling device either on the 230V network or via a photovoltaic system, whereby only one evaporator and one condenser are provided in the device. The basic requirement for this is an exact coordination of the refrigeration components and the refrigerant filling quantity. By locking the two compressors according to the invention, parallel operation of the compressors can be ruled out.

The advantages achieved with the invention are in particular that the photovoltaic system only has to be designed for daytime operation, while the cooling device can be operated on a 230V network during nighttime operation. In the case of ice cream chests in particular, it is possible to take into account the fact that when there is strong sunlight, the solar power compressor is operated with high energy consumption due to the required cooling effect, but conversely, in this case, a lot of power can also be provided by the photovoltaic system. Conversely, it can be assumed that during longer periods without sunlight, no ice cream will be sold anyway, so that all of the components of the photovoltaic system can be dimensioned accordingly small. To bridge the nighttime operation, such an ice cream chest can therefore easily be transported to the nearest network connection.

According to a preferred embodiment, the mains power compressor is locked when the photovoltaic system generates sufficient power to operate the solar power compressor. With such a system design, a hybrid supply is also conceivable, i.e. the cooling device is connected to both the 230V mains and the photovoltaic system. As soon as the photovoltaic system provides sufficient power, the mains operation is switched off and the mains power compressor is locked.

According to a further preferred embodiment, the solar power compressor is locked when the cooling device is operated with mains power. In this case, the mains power supply always has higher priority. As soon as the cooling device is connected to the mains, the solar power compressor is locked and cooling takes place exclusively by the mains power compressor.

According to a further preferred embodiment, a locking circuit is provided for locking both compressors, which deactivates the other when one compressor is activated. In particular, the locking circuit can consist of a relay that interrupts the power supply to the solar power compressor when the cooling device is connected to the mains power. In this way, a particularly simple locking of both compressors can be achieved, since only a simple relay is required, which responds when connected to the 230V network and activates an opener that interrupts the circuit of the solar power compressor.

According to a further preferred embodiment, an accumulator that operates the solar power compressor is integrated in the cooling device and can be charged via a charge controller. In particular, it can be provided that the accumulator can be charged using mains power as soon as the cooling device is operated with the mains power compressor. The accumulator can therefore bridge short periods without sunlight, provided the cooling device is operated via the photovoltaic system. In addition, it is ensured that the accumulator is always fully charged after being disconnected from the 230V network.

According to a further preferred embodiment, the photovoltaic system is integrated into the cooling device, with a solar panel being arranged on an outer wall of the cooling device. Such an embodiment should be chosen in particular if the cooling device is to be operated completely independently during the day. Of course, it is also conceivable to operate the cooling device according to the invention using a photovoltaic system located in a separate device, which supplies other consumers with electricity.

However, if the entire photovoltaic system is integrated into the cooling device, it is particularly advantageous to minimize the size and weight of the photovoltaic system, the accumulator and the charging controller so that the cooling device can only be operated during the day with the solar power compressor. This minimizes the weight of the cooling device and improves its handling.

Further details and advantages of the invention are explained in more detail below using an embodiment shown in the drawing. In this drawing:

Fig. 1 is a schematic representation of a refrigeration system of the cooling device according to the invention and

Fig. 2 is an electrical circuit diagram of the cooling device according to the invention.

Fig. 1 shows a schematic representation of a refrigeration system 1 of the cooling device according to the invention. The refrigeration system 1 consists in a manner known per se of a condenser 2, an evaporator 3 and a throttle element 4. A mains power compressor 5 and a solar power compressor 6 are connected in parallel to the refrigeration system, with the two compressors being operated alternatively. For this purpose, the refrigeration components and the refrigerant filling quantity are precisely coordinated.

Fig. 2 shows the electrical circuit diagram of the two compressors 5 and 6 according to Fig. 1. Electrically, the mains compressor 20 is connected to the neutral conductor N and to the conductor L1 of a 230V network via a motor protection 21 and a thermostat 22. The thermostat 22 is installed at a suitable location in the cooling device and closes the switch 22a as soon as a certain temperature is exceeded in the cooling chamber. In addition, a locking relay 23 is connected directly to the mains terminals L1 and N, which activates an opener 23a as soon as the corresponding mains supply is applied to the mains terminals L1 and N. Conversely, the opener 23a is in the closed position as long as there is no mains voltage applied to the terminals L1 and N.

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The opener 23a is in series with the main switch 24, via which the photovoltaic system 28 with the associated components can be activated. As soon as the relay 23 responds, the photovoltaic system is locked, so that the cooling device can only be operated by the mains compressor 20.

The photovoltaic system 28 consists of two solar panels 29 and 30, which are attached to the outer walls of the corresponding cooling device. The solar panels, which each deliver an output of 55 W in medium sunlight, for example, feed a charge controller 27, via which the accumulator 26 can be charged. The accumulator 26 finally serves as the voltage supply for the solar power compressor 31, which is activated via the electronic part 25 according to the switch positions of the switches 24 and 23a. The accumulator makes it possible for the solar power compressor to be operated even when there is no sunlight without additional energy supply from the photovoltaic system. In addition, it can be provided that the accumulator can also be charged via the mains power as soon as the cooling device is connected to a 230V network.

Claims (1)

9 August 1996
96-1575 G/Jp-hd Liebherr-Werk Lienz Ges.m.b.H., A-9900 Lienz Cooling device Protection claims: 1. Cooling device, in particular a deep freezer or ice cream freezer, with an evaporator, a condenser and a compressor that can be operated by a photovoltaic system with solar power, characterized, that a mains-powered compressor is installed in the refrigeration system in parallel to the solar power compressor, and that the mains power compressor and the solar power compressor are interlocked in such a way that only the mains power compressor or the solar power compressor can be operated. 2. Cooling device according to claim 1, characterized in that the mains power compressor is locked when the photovoltaic system generates sufficient power to operate the solar power compressor. 3. Cooling device according to one of claims 1 or 2, characterized in that the solar power compressor is locked when the cooling device is operated with mains power. -2- 4. Cooling device according to one of claims 1 to 3, characterized in that a locking circuit is provided for locking both compressors; when one compressor is activated, the other one is deactivated. 5. Cooling device according to claim 4, characterized in that the locking circuit consists of a relay which interrupts the voltage supply of the solar power compressor when the cooling device is connected to the mains power. 6. Cooling device according to one of claims 1 to 5, characterized in that an accumulator operating the solar current compressor is integrated in the cooling device, which accumulator can be charged via a charge controller. 7. Cooling device according to claim 6, characterized in that the accumulator can be charged by the mains current as soon as the cooling device is operated with the mains current compressor. 8. Cooling device according to claim 6, characterized in that the photovoltaic system is integrated in the cooling device, with a solar panel being arranged on an outer wall of the cooling device. 9. Cooling device according to claim 8, characterized in that the size and weight of the photovoltaic system, the accumulator and the charge controller are minimized in such a way that the cooling device can only be operated during the day with the solar power compressor.