DE2757204A1 - COMPRESSION COOLING MACHINE, IN PARTICULAR FOR REFRIGERATORS OR FREEZERS - Google Patents

Description

Compression refrigeration machine, in particular for refrigerators or freezers

The invention relates to a compression refrigeration machine, in particular for refrigerators or freezers, with several heat exchangers and a single-phase induction motor driving the compressor, whose torque can be changed electrically and as a function of at least one state variable of the refrigeration machine based on its actual torque requirement in at least two different operating states is customizable.

Compression refrigeration machines of the type mentioned have a changing torque requirement during their operation. During a relatively short start-up phase, this is sometimes many times higher than during the considerably longer normal operating phase. Particularly extreme conditions exist when the drive motor of the compression refrigeration machine has to start again before pressure equalization has taken place in the system of the refrigeration machine. The particular for

909826/0189

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these cases developed well-known initial relief in the form of overflow valves and bypasses bring with them a considerable improvement, but they are altogether complex and prone to failure only compensate for extreme peaks while the different torque requirements over the full duration of a cooling cycle remains as before. This means, however, that the drive motor of the compression refrigeration machine designed for the highest torque occurring during operation can only achieve its optimum efficiency for a short time due to the changing torque requirement during a cooling cycle and consequently can work even at its most economical consumption, while it has to work with less efficiency over the longest section of a running period. In this way there are considerable energy losses in the known compression refrigeration machines.

A proposal that has only recently become known for adapting the respective output engine torque to the actual torque requirement is fulfilled electronically the task assigned to him is flawless, but a considerable and relatively expensive circuitry effort is required to carry it out.

The object of the present invention is therefore to provide a particularly inexpensive and reliable circuit with which Ren help can influence the torque delivered by the drive motor of a compression refrigeration machine in such a way that that the drive motor can be operated with optimum efficiency at least over large sections of a cooling cycle and in this way has the lowest possible energy consumption.

909826/0189

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This task is wild with a compression chiller of the type ⁴ described in detail at the beginning: because the main winding of the motor has at least one tap and is connected to the "."! "Siand:: .; \ Vlie the refrigerating machine responsive switching element according to the required torque demand is partially or fully switchable.

With. Help me tapping the main winding according to the invention of the Moliu ·. Lot it is possible in a simple way, that from the engine output β: e torque to the in the course of a cooling cycle changing torque requirement of the compressor of a compression refrigeration machine adapt and so their drive motor at least over larger sections of the cooling cycle to operate economically with the highest degree of efficiency and thus also with the lowest consumption.

An advantageous development of the subject matter of the invention result! by the fact that the first tap to the largest and the full main winding to the middle, during the The required torque for the compressor is enispi i < Ii1

Although mil this training according to the invention only / * ti Metriebözusi ändt · compression;..:: Kai t enaschine detects -veiien, may be due to the characteristic of such chillers torque curve during a cooling cycle with just a tap with minimum effort to achieve a relatively high energy saving .

Further advantageous features of the invention characterized in the claims are set out in the following description with reference to an exemplary embodiment shown schematically in the drawing in the form of a simplified circuit diagram of a Resistance auxiliary phase asynchronous motor with tapped main winding explained.

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One symbolically shown in the attached single figure as a circuit diagram. ιderstands auxiliary phase asynchronous motor for a compression refrigeration machine is connected in a known manner with a connection line 11 to an alternating current source, for example a phase 12 and a neutral conductor 13 of a single-phase alternating current network. In the connection line 11 there are a temperature control switch 14 and a motor protection switch 15 in series with the asynchronous motor IO.

The resistance auxiliary phase asynchronous motor 10 has a main winding 16 and also an auxiliary winding 17, of which the latter lies in a line 18 parallel to the main winding 16. The auxiliary winding 17 can be switched on with the help of a relay 19 in series with the main winding 16, which contacts in the line 18 are dependent on the Stroa flowing in the main winding 16 briefly closes.

In the exemplary embodiment shown, the main winding 16 of the asynchronous motor IO is provided with a tap 20, from which a line 21 leads to a fixed contact of a switching element 22. This switching element 22 'lies between the relay 19 and the end of the main winding 16 in the main current circuit of the asynchronous motor. Its movable contact 23, designed as a changeover switch, can be switched between the already mentioned fixed contact at the end of the line 21 connected to the tap 20 and another fixed contact which is arranged in the connecting line between the hands of the main winding 16 and the relay 19 ¹ . Depending on the position of this movable contact 23, the main winding 16 is thus either fully or only partially switched on, that is to say up to the tap 20. The switching element 22, designed as a heat switch and as such preferably provided with a bimetal element, is in good heat-conducting contact on a dashed line in its outline.

909826/0189 _ ₅ _

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sen indicated evaporator of a compression refrigerator and switches the movable contact 23 depending on the temperature of this evaporator.

The resistance auxiliary phase asynchronous motor 10 for a compression refrigeration machine , represented by the illustrated and described switching ticket, operates in the following way:

As soon as the temperature control switch 14 responds as a result of a rise in temperature in the area monitored by in » , its contacts close and the circuit of the asynchronous motor 10 in series with it is closed. The relatively high starting current causes the relay 19 to close its contacts located in the line 18 so that the auxiliary winding 17 is switched on in the starting phase parallel to the main winding 16 until the relay 19 drops out again after the asynchronous motor has started up.

Since the evaporator of the compression refrigeration machine is initially still relatively warm in this start-up phase , the movable contact of the switching element 22, which is designed as a changeover switch , is on the fixed contact at the end of the line 21 leading to the tap 20 and assumes the position shown in dashed lines in the figure. This means that in this phase, when the evaporator is relatively warm, the main winding 16 is only partially switched on . This results in a high breakdown torque for the asynchronous motor in the start-up phase, which enables it to overcome the high start-up torque of the compressor of the compression refrigeration machine. The motor therefore runs in this phase with good efficiency for high loads.

In the course of the cooling cycle that now begins, the required torque decreases. At the same time, the evaporator of the compression refrigeration machine cools down. With decreasing

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Steam temperature now switches the movable contact 23 of the thermal coupling with the evaporator switch element 'J.'. uui, so that the hatip winding Ii- 'is not fully switched into the circuit. This reduces the magnetic flux in the Mcor and also its tilting moment, so that the much lower torque requirement at low evaporator temperature is taken into account and the actual tilting moment is adapted to the torque required in this phase. In this way, the asynchronous motor IO runs with a high degree of efficiency even with a lower breakdown torque, so that in this way a considerable amount of energy is saved.

If the lower switching point of the temperature control switch 14 is reached towards the end of the current cooling cycle, so öfi.: Et this its contacts, whereby the asynchronous motor is set again. Warmed up in the standstill phase that now follows the evaporator bi ^ by absorbing heat from the environment to the point where the switch 23 switches back to its starting position on the tap. When switching on the Temperature control switch 14 can then be the asynchronous motor start again with a high overturning moment.

Any known organ that responds to a change in temperature can of course be used as the switching element 22. It is only important that this switching element 22 is in direct heat-exchanging contact with the evaporator the compression refrigeration machine is at a standstill and performs its switchover function depending on the evaporator temperature.

Notwithstanding the illustrated and described embodiment, the number of taps can be arbitrary. It is in this case it is only necessary to design the changeover switch 23 accordingly as a step switch. However, it has been found that the desired energy savings can be achieved in the simplest possible way

90982S / 0189

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3> 27S720A

achieve with only one tap] ·: if this is so designed will that this the gröi'i.eu and the full main winding is assigned to an average torque occurring during operation of the compressor.

However, it is also within the scope of the invention that the said switch or ^; - it has its switching function instead of the temperature-dependent one it from the evaporator also depending on another during operation of the compression refrigeration machine changing state variable triggers. In particular, the temperature that changes in the course of the cooling cycle is also important of the customer or the pressure pipe of the compressor. In addition, however, the changing Pressure conditions on the suction and / or pressure side of the compressor can be used to trigger the required switchover function if instead of the temperature-dependent one a pressure-dependent organ is used.

4 claims
1 figure

909826/0189

Claims (4)

TZP 77/469 (1st compression chiller, especially for cooling or Freezers, with multiple heat exchangers and one single-phase induction motor driving the compressor, whose torque can be changed electrically and as a function of at least one state variable of the Chiller based on its actual torque requirement is adaptable in at least two different operating states, characterized in that that the main winding of the motor (10) has at least one tap (20) and one on the State variable of the refrigerating machine responsive switching element (22) according to the required torque requirement can be partially or fully switched on. 2. Refrigerating machine according to claim 1, characterized in that the first tap (20) the largest and the full main winding (16) a middle one, required during operation of the compressor Torque is assigned. 3. Refrigerating machine according to claim 1 or 2, characterized in that the triggering state variable the temperature of the heat exchanger, preferably the evaporator temperature, is used. 4. Refrigerating machine according to claim 1 or 2, characterized in that the triggering state variable the suction pressure is used. 4f 909826/0189