DE3623953C2 - - Google Patents

Description

The invention relates to an electrical defrost control for a compressor operated refrigeration system according to the generic term of Claim 1.

It is an electrical defrost control of this type from the US PS 30 29 611 known. With this control, as with other cooling units with automatic defrost for the purpose on the one hand to de-ice the evaporator and on the other hand a The temperature of the refrigerated goods increases during this defrosting phase avoid using a timer that runs after set time intervals turns off the compressor and an electric one Defrost resistance activated. But there is one of the temperature the bimetal switch, which switches depending on the evaporator, in order not to switch off the compressor longer than necessary, independent when reaching a certain temperature de-energized the timer and the compressor  switches on again. Switching off the compressor, however takes place depending on the switching process of the timer, which also switches on the defrost heater at certain intervals. With this design, the compressor remains switched off until the bimetal switch is flipped. The timer runs itself but continue. The specified intervals entered for him for switching on the compressor on the one hand or for switching off the compressor and switching on the defrost heater therefore do not take into account the length of time required for the defrosting process was effectively needed. This can happen with several extremely long defrosting processes, as is the case with severe icing of the evaporator can cause unnecessary after a much too short time Defrosting is initiated.

The present invention has for its object a To improve defrost control of the type mentioned at the outset in such a way that these defrost times of different lengths with a simple structure considered.

To solve this problem with a generic defrost control the characteristic features of the claim 1 provided. These features ensure that after The next defrosting process only ends when a defrosting process is finished after the duty cycle specified by the timer becomes.

Advantageous developments of the defrost control according to the invention are characterized in the subclaims, the Features of claims 2 and 3 bring the advantage, that the refrigerated goods stored in the immediate vicinity of the evaporator before defrosting due to the premature shutdown of the Fan is cooled to a temperature which is lower than the ambient temperature, while that versus reclosing of the compressor predetermined delay in switching on  of the blower causes the evaporator to very quickly reached the ambient temperature. It also prevents Air circulates inside the cooling unit through the just finished defrosting has been heated. The characteristics of claim 4 allow easy implementation the defrost control according to the invention.

In the accompanying drawing is an embodiment of the Defrost control according to the invention shown. The single figure shows the circuit diagram for the power supply in schematic form and defrosting a cooling unit.

In the figure, the circuit shown as a diagram of a cooling unit according to the invention is designated as a whole by ( 1 ). In the circuit ( 1 ) a line (L) for power supply with branches (L 1 , L 2 ) is provided, between which the potential difference of the network, for example 220 volts, is present. With ( 2 ) is an electrically operated compressor, which is connected in a conventional manner by a liquid line to an evaporator ( 3 ) and to a condenser, not shown. An electrically operated fan ( 5 ) is provided in order to forcibly obtain air circulation on the surface of the evaporator ( 3 ). In addition, in the vicinity of the evaporator ( 3 ), an electrical defrost resistor ( 6 ) is attached, which causes the defrosting of the evaporator ( 3 ) in a manner to be described in more detail below.

A temperature sensor ( 7 ) is also provided on the evaporator ( 3 ), which measures its temperature and is connected to the actuator ( 8 ) of a first switch ( 9 ). The changeover switch ( 9 ) has a movable contact ( 10 ) which is connected to the branch (L 2 ) of the line (L) and is alternately connected between a first and a second contact terminal, which are designated by ( 11 ) and ( 12 ) . The terminal ( 11 ) is connected to the movable contact ( 13 ) of a second changeover switch ( 14 ), which is also provided with a first and a second contact terminal ( 15 ) and ( 16 ).

An electromechanical timer ( 17 ) is connected in series in the line (L) with the defrost resistor ( 6 ); the timer ( 17 ) and the defrost resistor ( 6 ) are connected to one another via the terminal ( 15 ) of the second switch ( 14 ). The terminal ( 16 ) of the switch ( 14 ) is in turn connected to the terminal ( 12 ) of the first switch ( 9 ) and via this to the terminal ( 20 ) for the power supply to the compressor ( 2 ).

A second terminal ( 21 ) for supplying the compressor ( 2 ) is connected to the branch (L 1 ) of the line (L). At the terminals ( 16 ) and ( 12 ) the movable contact ( 22 ) of the switch ( 23 ) is also connected, which interrupts the supply of the blower ( 5 ) in a manner described in more detail below. The movable contacts ( 13 , 22 ) of the second switch ( 14 ) and the switch ( 23 ) are actuated in a conventional manner, for example via cams, by the timer ( 17 ).

The actuator ( 8 ) together with the temperature sensor ( 7 ) represents a thermal control system of the evaporator ( 3 ). This system has two switching thresholds, ie an upper one, for example at + 7 ° C, and a lower one, for example at -25 ° C lying threshold. When these thresholds are reached, the actuator ( 8 ) switches the contact ( 10 ) of the changeover switch ( 9 ) from the first ( 11 ) to the second terminal ( 12 ) or vice versa on the signal from the temperature sensor ( 7 ), as described in more detail below is.

During normal operation of the cooling unit, in which, for example, a temperature of the evaporator ( 3 ) between + 7 ° C and -25 ° C is assumed, the contact ( 10 ) of the first switch ( 9 ) closes the connection to the terminal ( 12 ) , whereby the compressor ( 2 ) is supplied with power. The contact ( 13 ) of the second switch ( 14 ) connects to the terminal ( 16 ) and the switch ( 23 ) supplies the blower ( 5 ) with current.

The internal resistance of the timer ( 17 ) is considerably higher than that of the defrost resistor ( 6 ). For this reason, the effect of the defrosting resistor ( 6 ) due to the current flowing through the timer ( 17 ) can be neglected; this current is so low that there is no appreciable heating of the resistor ( 6 ). After a predetermined time, the timer ( 17 ) actuates the switch ( 23 ), whereby the power supply to the blower ( 5 ) is interrupted. The evaporator ( 3 ), which is no longer forced-ventilated, experiences a temperature drop which is sensed by the sensor ( 7 ). When the lower threshold value is reached, the signal emitted by the sensor ( 7 ) is such that the actuator ( 8 ) is activated, as a result of which the contactor ( 10 ) of the first changeover switch ( 9 ) is switched to the terminal ( 11 ). The compressor ( 2 ) continues to work because it is supplied via the second switch ( 14 ), whose contactor ( 13 ) closes the contact to the terminal ( 16 ). After a certain switch-off time of the fan ( 5 ), the timer ( 17 ) actuates the contact ( 13 ) of the second changeover switch ( 14 ) and switches it from the terminal ( 16 ) to the terminal ( 15 ). The timer ( 17 ) is stopped because it is short-circuited in the branch (L 2 ) of the line (L), the defrost resistor ( 6 ) being activated at the same time.

The defrost resistor ( 6 ) causes the evaporator ( 3 ) to heat up, the temperature of which is constantly checked by the temperature sensor ( 7 ). If the temperature of the evaporator ( 3 ) exceeds the upper threshold value specified by the actuator ( 8 ), the contact ( 10 ) of the first switch ( 9 ) is switched over again from the terminal ( 11 ) to the terminal ( 12 ). In this way, the power supply to the defrost resistor ( 6 ) is interrupted while the power supply to the compressor ( 2 ) and the timer ( 17 ) is restored.

After it is switched on again, the timer ( 17 ) switches the contact ( 13 ) of the second switch ( 14 ) back to the terminal ( 16 ) and acts on the switch () after a certain predetermined time after the compressor ( 2 ) has been switched off. 23 ) to switch the fan ( 5 ) back on.

Claims (4)

1.Electrical defrost control for a compressor-operated refrigeration system with a timer ( 17 ) and a first changeover switch ( 14 ) actuated by the latter, which switches the operating current for the refrigeration system from the compressor ( 2 ) to a defrost resistor ( 6 ) on the evaporator ( 3 ), and with a second changeover switch ( 9 ), which by means of a temperature sensor ( 7 ) assigned to the evaporator ( 3 ) and registering the temperature of the evaporator ( 3 ) registers the operating current when a predetermined upper temperature value is reached Defrosting resistor ( 6 ) switches back to the compressor ( 2 ) and the refrigeration system to cooling mode, characterized in that the timer ( 17 ) is stopped by actuating the first switch ( 14 ) until the operating current from the defrosting resistor ( 6 ) to the compressor ( 2 ), controlled by the second switch ( 9 ), is switched back, and that then the timer ( 17 ) restarts with the predetermined duty cycle. 2. Electrical defrost control according to claim 1, characterized in that the evaporator ( 3 ) is associated with an electrically operated blower ( 5 ), which of the timer ( 17 ) via an on / off switch ( 23 ) with respect to the start of the compressor ( 2 ) can be switched on with a time delay. 3. Electrical defrost control according to claim 2, characterized in that the fan ( 5 ) from the timer ( 17 ) via the on / off switch ( 23 ) can be switched off with a time advance compared to switching off the compressor ( 2 ). 4. Electrical defrost control according to claim 1, characterized in that the timer ( 17 ) and the defrost resistor ( 6 ) between the branches (L 1 , L 2 ) of an electrical supply line (L) are connected in series, that the movable contact ( 10 ) of the second switch ( 9 ) is supplied by the branch (L 2 ) of the supply line (L), to which the timer ( 17 ) is also connected, and alternately the contact to the compressor ( 2 ) or to the movable contact ( 13 ) of the the first switch ( 14 ) closes, while the movable contact ( 13 ) of the first switch ( 14 ) when the movable contact ( 10 ) of the second switch ( 9 ) comes into contact with it, alternately the contact to the compressor ( 2 ) or to the defrost resistor ( 6 ) closes.