DE3109366A1 - Method and apparatus for melting the ice formed on the evaporators of heat pumps or refrigerating plants - Google Patents

Abstract

A method and a device are described for melting the ice formed on the evaporators of heat pumps or refrigerating plants. The melting process is controlled in dependence on the change in physical size measured in the region of the evaporator. The melting process is initiated and terminated by the change in the heat transmission values of two measuring elements.

Description

Process and device for defrosting the frost deposits

The invention relates to evaporators of heat pumps or refrigeration systems a method for defrosting the frost on evaporators of heat pumps or refrigeration systems, in which the defrosting process depends on the change in one in the area of the evaporator measured physical quantity is controlled.

From Danfoss Journal, No. 3, 1967, page 8 it is known the evaporator defrosting refrigerated and freezer units using a pressure switch. The pressostat recorded the differential pressure in the air circuit of the evaporator and, if the Differential pressure when frost forms the defrosting process, with defrosting by feeding by hot gas or with the help of electric radiators. The defrosting process is terminated when the pressure in the evaporator as a result of melting down to a predetermined value Value has dropped.

However, this method using differential pressure measurement is technical very expensive and because of the metrological recording of the small differential pressure change problematic.

The object of the present invention is therefore to provide a safe driving Provide defrosting that is inexpensive with little technical effort is working.

This object is achieved according to the invention in that the defrosting process initiated and ended by changing the thermal conductivity values of two measuring elements will.

It has been shown to be beneficial to the changes in thermal conductivity to measure these changes since no high electrical power is required to make practically measurable.

Namely, if a measuring element is supplied with constant electrical power to, its temperature changes significantly at first, but this change sounds and after some time a steady state is reached. In this stationary There is a balance between the supplied and the surface of the state Measuring element dissipated energy.

A change in the state of equilibrium, e.g. due to a change in temperature, causes more energy to be dissipated and thus the self-heating of the measuring element is reduced.

The lowering of the self-heating and thus the thermal conductivity in turn, causes a change in resistance, which at constant current a measurable one Causes voltage change.

The use of the method according to the invention makes a cost-effective one and reliable defrosting on demand with a small footprint. aside from that the coefficient of performance in heat pumps is significantly improved.

The defrosting process is advantageously initiated when the frost has set a predetermined value on the evaporator, determined by the distance between the defrosting process Measuring element reached by the evaporator certain thickness. With this measure it is possible to set the temperature on the evaporator to any given temperature, which results from the thickness of the frost build-up on the evaporator, to increase.

The defrosting process is preferably ended when the coldest Place of the evaporator temperature recorded by the measuring element ending the defrosting process reached a predetermined value. This ensures that the entire evaporator has been defrosted.

A device for carrying out the method according to the invention with evaporators has two measuring elements that respond to changes in the thermal conductivity, preferably semiconductor sensors. These measuring elements are via a selection circuit connected to a relay which releases a defrost signal to a defrost device. The measuring element initiating the defrosting process is at any point of the evaporator arranged at a distance corresponding to the permissible frost build-up. The measuring element ending the defrosting process is advantageously at the coldest point of the evaporator arranged.

The method according to the invention is particularly advantageous for all of them Cold storage systems and heat pumps with frosting air coolers are used.

In the following, the method according to the invention is based on an exemplary embodiment, which is shown schematically in a drawing, explained in more detail: In this Embodiment semiconductor sensors are used as measuring elements.

A semiconductor sensor 1 is via a flip-flop 2 and a timer 3 is connected to a selection circuit 4, e.g. an RS memory. A second semiconductor sensor 5 is also via a flip-flop 6 and a switch 7 via a gate 8 connected to the RS memory. The RS memory is on the output side via a timing element 9 and a power amplifier 10 with a relay 11 or via a power amplifier 12 with a relay 13 in connection.

The semiconductor sensor 1 is provided with a degree of frost that corresponds to the permissible degree of frost Distance mounted on the evaporator. If the ripe set reaches the during operation Semiconductor sensor 1, the line 14 with constant current, for example 10 mA, is fed, the thermal conductivity and thus the resistance of the changes Semiconductor sensor 1, and a voltage change (since constant current occurs. This change in voltage causes flip-flop 2 to turn on. This will the timer 3 is activated, which after the set time has elapsed, e.g. a Minute that RS memory 4 sets. The prerequisite for setting the RS memory is that on the semiconductor sensor5, which is mounted at the coldest point of the evaporator, there is a predetermined temperature of, for example, + OOC and the external switch 7 is closed. This switch 7 serves as a lock switch and causes either a defrost can only be carried out during the day or only at night.

By setting the RS memory 4, the timing 9 and the Power amplifier 10 locked, so that the relay 11 is de-energized. Simultaneously controls the power amplifier 12 and relay 13 is connected to voltage.

This initiates the defrosting process. Defrosting can go through Supply of hot gas or take place with the help of electric heaters.

If the temperature at the semiconductor sensor rises during the defrosting period 5 to a predetermined value, for example + 50C, or the switch opens 7, the RS memory 4 is reset. The power amplifier then locks 12 and relay 13 are de-energized, the defrosting process is ended.

After the set delay time has elapsed on the timer 9, for example 30 seconds, the power amplifier 10 and thus the relay 11 controlled. The heat pump resp.

the refrigeration system has started.

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Claims (7)

Claims 9 method for defrosting the frost build-up on evaporators of heat pumps or refrigeration systems, in which the defrosting process depends on the change in a physical variable measured in the area of the evaporator is controlled is characterized in that the defrosting process is achieved by changing the thermal conductivity values two measuring elements is initiated and terminated. 2. The method according to claim 1, characterized in that the defrosting process is initiated when the frost build-up on the evaporator has reached a predetermined level Distance between the measuring element initiating the defrosting process and the evaporator determined Thickness reached. 3. The method according to claim 2, characterized in that the defrosting process is ended when the coldest point of the evaporator by the defrosting process terminating measuring element detected temperature reaches a predetermined value. 4. Device for performing the method according to one of the claims 1 to 3 with evaporators, characterized by two changes in the thermal conductivity appealing measuring elements, of which one measuring element initiates the defrosting process and the other measuring element ends the defrosting process, and the measuring elements via a Selection circuit connected to a relay, which sends a defrost signal to a defrosting device releases. 5. Apparatus according to claim 4, characterized in that the the Defrosting initiating measuring element at any point on the evaporator with arranged at a distance from the evaporator corresponding to the permissible frost build-up is. 6. Apparatus according to claim 4 or 5, characterized in that the measuring element ending the defrosting process at the coldest point of the evaporator is arranged. 7. Device according to one of claims 4 to 6, characterized in that that the measuring elements are designed as semiconductor sensors.