DE1814070C - Defrost control device for electric refrigerators - Google Patents

Description

The invention relates to an electronic 50 and, depending on a second, Hö control circuit for the defrosting of the heat sink, which is the removal of the ice of an electric refrigerator with a thermistor indicates the defrost cycle is terminating. In addition as a temperature sensor that turns on or off an electrical switch with an between switch a heating element provided switching two positions - according to beginning and end element controls via a control transistor. 55 of the defrost cycle - movable actuator arm It is known that cooling efficiency uses one. The normal operation between electric cooling device is reduced if the actuating arm is held in both positions the cooling device or on the surface of the by a thermal expansion element after the over evaporator Ice precipitates, and it is very twisting a bias that is laying down the important to remove the ice and the cooling is effective- both temperatures, moves, the ability of the electric cooling device to be increased. These two systems essentially work Procedure that is very common for removing ice using the same principles. Upon reaching a was used is to have a lower temperature defroster valve will defrost the cycle to open for a predetermined period of time and automatically begin and upon reaching the itself to allow hot gas to flow through the evaporator 65 by the upper temperature that sets the defrosting or a heater for a predetermined temperature ends the defrosting cycle. This brings Time period to energize and they generate heat, however, the disadvantage that the defrosting too leave. Since the duration of the defrosting cycle also begins when only the

3 4

The temperature of the temperature sensor is sufficiently heated or the main circuit is opened to has sunk without a layer of ice forming on the heating device as required, the evaporator.

The icing cycle therefore also depends on the amount of a heater, with terminals 1 and 2 one Chilled goods stored in the refrigerator. Connected to 5 AC power source. The facility 3 the space not filled by refrigerated goods is very small, a relay can be used to operate a hot gas ? <ne cooling of the air valves in it. The defrost controller yes fast, so that the de-icing cycle sits a silicon-controlled rectifier 4, a can throw leuende temperature reached. As a result, transistor 5, which is switched on and off when it is possible that the cooling period compared to io the silicon-controlled rectifier 4 on or off the defrost cycle is very short, making one a DC bias supply device effective cooling of the goods to be cooled is no longer guaranteed for the transistor 5, a thermistor 7, which therleisi.t Furthermore, it can happen that the mix with the interior of the freezer for Defrosting cycle begins when already frozen detecting a change in temperature Küäiiiut is introduced into the refrigerator. 15 is coupled within the freezer, a

} :: The invention is based on the object of creating a base bias voltage dividing resistor 8, voltage sec-r onic control circuit of the dividing resistors 9 and 10 mentioned at the beginning for dividing the part, in which a defrosting of any alternating current voltage when the silicon, . can throw introduced · ice and is used ao, a diode 11 for rectifying the by v "- inabhängig on the thickness of an already gebil- controlled rectifier 4 in its off state loading dc ■■ -. indiger removal of the ice layer reliably the resistors 9 and 10 divided voltage, a k et throw. Charging condensate OT 12, a switch 13, the normal

This problem is solved in that the switchgear is open and can be started immediately ei;: nt is closed with the control transistor in a loop of the defrosting process, a d>; t is switched that a conduction state of the »5 base resistance 14 for the transistor and a S ^ transistor a switching state of the switched collector resistor 15 for the transistor 5. η: ts is assigned and that this switching state is in the circuit [described above

d. Conduction state of the control transistor in terms of the silicon-controlled rectifier 4 in its d ·. En maintenance influences that furthermore a blocking state and the switch 13 is provided in its Otten-Sii-ülter, when it closes the 30 position in the normal state, ie in the state, S ^1. -1 ^! transistor switches through the switching element, and at which does not require defrosting. Thus sawn d: ■■ & finally the thermistor with the Steuertran- is found that the heater 3-containing si circuit, or connected in such a way is that this the switch in its open state, and it is locked by the fcrekrnent if the! Temperature at the heater 3 generates no heat. In the above mentioned chlorine reached a predetermined value. 35th state, the voltage of the alternating

In the control circuit according to the invention there is a power source via the silicon-controlled "» «chsomit the initiation of defrosting by closing the rectifier 4. and it is the condenser 12 through the of the resistors 9, 10 connected in parallel to a voltage divider and charged by the diode 11 instead of the. The voltage occurring across the capacitor 12

The circuit arrangement opens after a short voltage depends on the voltage division ratio early closing of the switch - similar to one of the resistors 9 and 10. The emitter-base-Mrecke monostabilcn multivibrator - in a stable the transistor 5 is due to the above voltage before-state, from which they are biased only by changing the downward so that the transistor 5 is in his Resistance of the thermistor brought out throw conductive state is kept. Accordingly can. In the case of the defrosting device according to the invention, no ignition current flows to the gate circuit of the silicon core Control circuit therefore at any time then initiated controlled rectifier 4 connected to the collector throw when the thermistor is connected to a temperature of the transistor 5, the siUziumratur which is lower than the predetermined controlled rectifier 4 also in its S »perr temperature is in which the defrosting process is maintained.

finished throwing. This has the advantage that 50 The switch 13 can be closed to the that the defrosting arbitrarily and independently of being in the state described above the thickness of an already formed layer of ice. The defrosting control circuit controls the defrosting process can throw. To give instructions on how the defrosting

The invention throws in the following see on hand control circuit is brought into defrosting set, matic drawings of exemplary embodiments 55 This purpose can thereby be approached without difficulty explained. be filled that the switch 13 a Zeitghed F i g 1 shows an electrical circuit diagram of an assigns so that the switch 13 periodically below the Embodiment of the inventive control effect of the timer can throw closed, circuit, and it is assumed that the switch 13 by the Fig. 2 shows an electrical circuit diagram of an effect of the timer momentarily closed further embodiment of the invention. Then the electrical charge that is up Control circuit. has accumulated in the capacitor 12, by the invention is a thyristor, z. B. a closed switch 13 discharged to the transilicon controlled Rectifier (controlled SiIisistor 5 to block. As a result, an ignition current flows zium rectifier) with a heating device in series 65 for gate switching of the silicon-controlled synchronism, 1 in a main circuit ters4 and brings this into its conductive state, where the silicon controlled rectifier lies in this leads to the closing of the main circuit, which its conducting state or blocking state for the closing of connection 1 of the alternating current source, the earth

5 6

heater 3, the silicon-controlled rectifier 4 and despite any increase in the resistance of the

comprises terminal 2 of the AC power source. The thermistor 7 is stored in the capacitor 12

Heater3 is thus energized to cope with the discharge and is not brought into the blocking state,

remotely from within the freezer until the switch 13 is closed again. Therewith

collected ice to begin with. 5 the circuit is in the state of the cooling process

Because the silicon controlled rectifier 4 is held in one.

Instantly brought into its conductive state The above description referred to a draft and the forward voltage drop across the frost control circuit, which has a thyristor in the conductive silicon-controlled rectifier 4 rather form a P-type silicon-controlled rectifier small or on the order of a few volts io If, however, one of the above Entist occurs, a voltage of such a magnitude that the circuit similar to the frost control circuit will keep transistor 5 in its conductive state will be caused by an N-type silicon plug not across or in parallel with the capacitor 12 used rectifiers,
when the switch 13 is opened again. Thus, F i g. Figure 2 shows a defrost control circuit which keeps transistor 5 continuously in its off-state 15 such N-type silicon controlled equilibrium while using the defrost controller. The N-type silicon-controlled circuit is kept in operating condition, what rectifier is denoted by reference numeral 16, is completely the same as when the switch 13, as can be seen from Fig. 2, has a Tran continuously held in the closed position. Thus, the heater 3 continues to generate heat so that ao F i g. 1 is opposite transistor 5 shown. the defrosting process for removing ice. The transistor 17 is of the pnp type and is with one continuing inside the freezer. DC bias supply means 6, a

As soon as the diode 11 and a capacitor 12 in an assignment

the collected ice is removed, the temperature rises, which completely corresponds to the assignment

gradually increases within the freezer, as measured in FIG. 1 is the opposite. In Fig. 2 are

at the resistance of the thermally with the interior for the designation of the same parts, as they are also in

the freezer coupled thermistor 7 of FIG. 1 appear, use the same reference symbols

gradually decreases. This leads to the fact that the base has been det. The operation of transistor 17 and

Emitter path of the transistor 5 through the chip of the silicon-controlled rectifier 16 in the circuit

voltage is biased deep forward, which by division according to Fig. 30. 2 is the same as in the case of after

len the voltage of the DC bias Fig. 1, i.e. that is, during the cooling process, the transistor

delivery device 6 through the thermistor 7 and through 17 in its conductive state and the silicon

the resistor 8 is obtained. At one point, controlled rectifier 16 in its blocking state

which is used to maintain the temperature inside the freezer.

device reaches the defrost stop temperature, 35 Therefore, the silicon controlled rectifier 16 the transistor 5 changes from its blocking state, not triggered, to the circuit in this state in its active area so that there is a decrease to become conductive. If in the circuit there is a scarf results in the ignition current, which is immediately closed to the silicon ter 13, the in controlled rectifier 4 is performed. electric charge accumulated in the capacitor 12

Therefore, the conduction angle of the silicon-controlled 40 is discharged by the switch 13 to the transistor 17 rectifier 4 now smaller than 180 °, and to block it. This has the result that the silicon-controlled appears to find a phase in which no conduction, rectifier 16, is brought to conduction. During the non-conductive phase of the silicon that the defrosting process by the heater 3 zium-controlled rectifier 4, the condensation is started. Thereafter, a process is effected, the battery 12 is charged, and a voltage 45 appears which is completely equal to that in FIG. 1 is to remove above or parallel to the capacitor 12. This chip ice that has accumulated inside the freezer is also attached to the base of the transistor 5, the defrosting being laid so that the transistor is more and more process stops automatically as soon as the ice approaches its conductive state. In the meantime it has been completely removed
time occurs in the silicon-controlled rectifier 4 50 In combination with the silicon-controlled rectifier, the so-called positive feedback occurs, in the case of the rectifier in the circuits according to Figs . be turned. While the arrangement in Fig. 1 This leads to the transistor being quickly in its and 2 such that the voltage across the thyristor and the silicon-controlled DC voltage is quickly divided by the volt dividing resistors 4 into its blocking state and this divided voltage across the charge is used to re-open the main circuit and means of the diode and the capacitor to stop the defrosting process, that is to say the heating is applied to the base of the transistor, so the process of the heater 3. is clear that another arrangement in the way

After the transistor S in the conductive application 60 can be met that one over the charge incurred and the silicon-controlled rectifier 4 in the direction occurring voltage initially through the the blocking state is brought, the temperature voltage dividing resistances are maintained and these within of the freezer is decreased and the divided voltage is then applied to the base of the transistor to transistor S deeply biased by the tension that is being guided.

1 sheet of drawings

Claims (2)

is preset, it is inevitable that the EntPatent claims: freezing process will differ depending on the amount of ice that has been deposited. 1.Electronic control circuit for the defrosting If the amount of ice deposited is relatively large, the heat sink of an electric cooling device is not completely removable, the device with a thermistor as a temperature sensor, and when the amount of ice is relatively small, the defrosting rod, which is a or switching off a heating element continues even after the ice has been completely removed from the provided switching element via a dig, which controls the temperature in the control transistor, thereby marked- cooling space rises to an unnoüg high level, net that the switching element (4) with the control io There is already an electronic control circuit transistor (5) connected in a loop for defrosting the heat sink of an electric unit, so that a conduction status of the control panel cooling device with a thermistor as a lempesistor a switching status of the switching element is known (U.S. Pat. No. 3,248 and that this switching state influences the one for switching on and off a Heizele line state of the control transistor in the sense of 15 Mentes provided switching element over emen Iran its maintenance that also controls sistor , in which when reaching emer upper a switch (13) is provided at which Temperature of the thermistor of the de-icing cycle Closing the control transistor, the switching element should be terminated. For this purpose, the thermistor is switched on, and finally the thermistor (7) arranged directly adjacent to the cooling element is connected to the control transistor in such a way that the ice that forms on the cooling element is bound Switching element blocks, enclosing the thermistor, its temperature drops when the temperature at the thermistor increases, whereupon its resistance rises. Voltage at one voltage divider tap for so long. 2. Electronic control circuit after on until a Zener diode, which is in parallel, becomes conductive Claim 1, characterized in that the 15 So that a transistor is switched through Dun ι Switching element is a thyristor (4) that furthermore the current flowing through it is ei a diode (11) when the thyristor is off, heats the heating resistor, which in turn heats a. ' an alternating voltage, which is parallel to this, closes the thermal switch that brings the zui rectifies and switches on the heating element serving at the base of the control transmission de-icing (5) To maintain its conductivity, another thermal switch is switched on state, the resistor in its blocked state is connected in series with the thermistor, the thyristor via one of the collector of the control, whereby the voltage applied to the zener diode transistor connecting to the ignition electrode is increased. This creates a shutdown temperature Line ignites that continues to set the thermistor (7), which is higher than that at which the Durchin a voltage divider circuit on the one hand to cut off voltage of the Zener diode at the beginning of the separation Connection of a DC voltage source that has reached the icing cycle. Through the serves to power the control transistor, heating element-induced temperature rise drops and, on the other hand, the resistance of the thermistor at its base. Does he reach you it is concluded that it switches the transistor on when it reaches the value at which the voltage across the zener diode the predetermined temperature switches through, and 40 below the breakdown voltage drops, so that finally the switch (13) blocks the voltage, which also blocks the transistor divider is connected in parallel in such a way that when it is, the heating resistor cools down again and Close the voltage supplied by the diode and the thermal switches return to their original position voltage derived and the transistor is blocked. Switching state can be switched back. 45 Furthermore, a mechanical system is known (USA.-Patent 3 320 386), in which, depending on ability of a predetermined temperature on the evaporator that is low enough to prevent the accumulation of ice causing a de-icing cycle to