DE10326329A1 - Refrigeration device with controlled dehumidification - Google Patents

Abstract

In the case of a no-frost refrigerator with at least one storage compartment (1), an evaporator (5) which is arranged in a chamber (8) which is separate from the storage compartment (1) and is alternately switched on and off and a fan (9) for circulating air between the storage compartment (1) and the chamber (8) of the evaporator (5), the mean circulation capacity of the fan (9) in a switched-on phase of the evaporator (5) is made variable in order to increase the temperature of the evaporator by increasing the circulation capacity and to shorten the duration of the evaporator's switch-on phases and thus to reduce the dehumidification in the storage compartment or to lower the temperature of the evaporator by reducing the circulation capacity and to extend the duration of the evaporator's switch-on phases and thus to increase the dehumidification in the storage compartment.

Description

The The present invention relates to a no-frost refrigerator and an operating method for such a Device.

at such refrigeration equipment an evaporator arranged in a chamber separated from a storage compartment for refrigerated goods, and heat exchange between the chamber and the storage compartment through which the storage compartment is cooled, is done by cooling and drying the evaporator with the help of a fan Air is blown into the storage compartment and relatively warm, moist air is emitted the storage compartment is sucked into the chamber. The storage compartment is not just cooled, but also dehumidified. The moisture condenses on the evaporator. By This dehumidification will prevent critical climatic conditions conditions especially when using the refrigerator in a warm environment Environment with high air humidity, condensation on shelves and refrigerated in the storage compartment. However, this advantage can be felt in less critical environmental conditions turn into a disadvantage when stored food through the intensive dehumidification can be dried out.

It there is therefore a need for a no-frost refrigerator and an operating method for a such a refrigerator, the one flexible adaptation to the climatic conditions in the vicinity of the Enable refrigeration device.

The Task is solved through a refrigerator with the Features of claim 1 and a method with the features of claim 10.

while the circulation rate the fan of such a refrigerator varies at the same time that at a given temperature difference between the storage compartment of the refrigerator and the Evaporator heat flow occurring between the both changed. This means, a reduction in circulation leads to a reduced heat exchange and thus a stronger one cooling down of the evaporator. This reinforced Cooling causes more intensive drying of those passing the evaporator Air. At the same time, the reduced circulation capacity causes that when evaporator and The fan is switched on, slow down the cooling of the storage compartment goes than with a higher one circulation rate, so that the duty cycle of the evaporator is extended. This renewal compensates for the reduced circulation and leads to, that in the course of a switch-on phase of the evaporator at lower Circulating more moisture is trapped than in high.

A variable circulation capacity of the evaporator can be easily realized by that the fan is in the on phase of the evaporator is made temporarily switched off. A control circuit is preferred provided to control the operation of the evaporator and the fan, which is set up to switch the fan on when the evaporator is switched on to operate intermittently and thereby its average circulation capacity in Throttling compared to continuous operation.

It can be a selector switch provided on the refrigerator that allows a user to desired duty cycle for the intermittent operation of the fan and so manually the drying effect of the refrigerator to the Adapt to needs. In a more comfortable design, the Control circuit to at least one climate sensor for detecting a Climate parameters such as the ambient temperature of the refrigerator, the Humidity of the ambient air or the humidity of the air in the Coupled interior and set up to the duty cycle in Dependence on the at least one climate parameter detected by such a sensor to control.

one According to another embodiment, the fan is switched on Phase of the evaporator to different non-disappearing speeds adjustable to the average circulation capacity to adapt to the needs. A selector switch can also be provided here, which allows a user to control a fan control circuit desired Speed of the same to specify, or the control circuit can on at least one climate sensor to be coupled to the circulation capacity of the Fan based on a climate parameter detected by this sensor and a predetermined target value of the air humidity automatically to control.

• a) Abschätzen eines Feuchtigkeitswertes in dem Lagerfach des Kältegerätes,
• b) Wählen einer Umwälzleistung für den Ventilators in Abhängigkeit von dem abgeschätzten Feuchtigkeitswert;
• c) Betreiben des Ventilators mit der gewählten Umwälzleistung.

The invention also relates to a method for operating a refrigeration device of the type described above, comprising the steps:

• a) Estimating a moisture value in the storage compartment of the refrigerator,
• b) selecting a circulation capacity for the fan as a function of the estimated moisture value;
• c) operating the fan with the selected circulation capacity.

The estimate is preferably a humidity measurement carried out directly in the storage compartment concerned. It is then possible, in particular, to influence the operation of the evaporator and the fan on the air humidity in the storage compartment when selecting the circulation capacity account. In principle, however, it is also possible to estimate the air humidity in the storage compartment on the basis of variables correlated with it, such as the temperature and air humidity of the environment, and to select the circulating capacity as a function of the result of the estimation.

Further Features and advantages of the invention result from the following Description of exemplary embodiments with reference to the attached Characters.

It demonstrate:

1 1 shows a schematic illustration of a no-frost refrigeration device according to the invention,

2 a timing diagram of the operation of the evaporator and fan according to a first embodiment of the invention; and

3 a timing diagram analogous to that of 2 for a second embodiment of the invention.

1 is a schematic representation of a combination refrigerator on which the present invention is implemented. A fridge 1 and a freezer 2 form two temperature zones of the refrigerator. A refrigerant circuit includes a compressor 3 , the compressed refrigerant in succession through two evaporators 4 . 5 of the freezer 2 or the refrigerator compartment 1 pumps, as well as a heat exchanger 6 that in the evaporators 4 . 5 relaxed refrigerant goes through before it returns to the compressor 3 entry. The cooler 1 assigned evaporators 5 is in one of the refrigerator compartment 1 through a thermally insulating wall 7 separate chamber 8th accommodated. The chamber 8th communicates with the refrigerator compartment 1 via air inlet and outlet openings, with a fan in one of these 9 for forced circulation of air between the chamber 8th and the refrigerator compartment 1 is arranged.

A control circuit 10 is with a temperature sensor located in the refrigerator compartment 12 and via control lines to the compressor 3 and the fan 9 connected and is able to the compressor 3 and the fan 9 - and indirectly via the compressor 3 the evaporators 4 . 5 - depending on one from the temperature sensor 12 switch the detected temperature on or off. The control circuit 10 is also connected to a humidity sensor 13 connected the one in the refrigerator compartment 1 is arranged. At the control circuit 10 can be a user-operated selector switch 11 be provided, which allows a target value for the humidity in the refrigerator compartment 1 adjust.

The air humidity sensor 13 in the refrigerator compartment 1 can also be replaced as a variant by a humidity sensor outside the refrigerator compartment and / or a sensor for the ambient temperature of the refrigerator, since their measured values allow conclusions to be drawn about the humidity in the refrigerator compartment 1 allow.

2 illustrates the operation of the control circuit 10 based on the time profiles of a plurality of operating parameters of the refrigerator. The curve 3 ' gives the operating status of the compressor 3 on. At time t _{0 it} is switched off; once the temperature sensor 12 if an upper limit temperature is exceeded, at time t ₁ , it is switched on until a lower limit temperature in the refrigerator compartment until time t ₂ 1 is undercut. From this time on the refrigerator compartment heats up 1 again until a new start-up phase of the compressor at t ₄ 3 starts.

From t ₀ to t ₁ is that of the sensor 13 recorded humidity in the refrigerator compartment 1 at a constant, low level. When the compressor is switched on 3 the fan also goes at time t ₁ 9 in operation, like through a curve 9 ' shown. The temperature of the evaporator 5 , represented by a curve 5 ' , goes back from a rest value T ₀ to a value T ₁ . Moisture from the fan 9 circulated air hits the evaporator 5 down so the humidity 13 ' until time t ₂ when the fan is switched off 9 slowly decreases. The moisture rises from time t ₃ 13 ' strongly, for example because the door of the refrigerator is opened and warm, moist air penetrates from outside. The control circuit 10 recognizes that more intensive drying is required and operates the fan 9 if at time t ₄ the compressor 3 is switched on again, intermittently with a pulse duty factor which is selected as a function of the air humidity detected at time t ₄ . This leads to an average lower circulation capacity of the fan 9 than during the time interval t ₁ to t ₂ , so that the heat exchange between the evaporator 5 and the refrigerator compartment 1 is slowed down. The switch-on period t ₄ to t ₅ is therefore longer than the period t ₁ to t ₂ , and the temperature T _{2 of} the evaporator reached during this period 5 is lower than T ₁ . This lower temperature T ₂ leads to that on the evaporator 5 air flowing past is dried more effectively, and due to the longer duty cycle of the compressor 3 a low humidity value is finally reached again.

The duty cycle with which the control circuit 10 operates the fan during the switch-on phases of the evaporator, in the simplest case it is a step function which has the value 1 for low air humidities and a non-disappearing value less than 1 for high air humidities; it it is also possible to use a step function with a large number of duty cycle values that decrease with increasing humidity or a continuous function for control.

In a second embodiment of the invention, the control circuit is 10 designed for different fan speeds depending on a measured humidity 9 adjust. The operation of this configuration is in 3 shown. If the air humidity is low, the evaporator starts up 4 the ventilator 9 at maximum speed, and the timings of on and off phases, evaporator temperature and humidity are the same as in the case of 2 , As a result, the diagram of the 3 until time t ₄ not of that of 2 , The control circuit selects at time t ₄ 10 based on the high humidity value measured at this point in time, a fan speed 9 that is less than its maximum speed. During the operation of the compressor and the fan, the air humidity decreases continuously and the speed of the fan increases accordingly 9 that the control circuit 10 based on the measured air humidity and with increasing fan circulation 9 the temperature of the evaporator also rises 5 over a large part of the time interval t ₄ to t ₅ .

In the 2 and 3 the case of rapid drying is shown, in which a single switch-on phase t ₄ to t ₅ is sufficient to return the air humidity in the refrigerator compartment to a target value. Of course, the drying process can also be spread over several successive switch-on phases.

Both 2 and 3 it was assumed that the maximum circulation capacity of the fan 9 corresponds to a desired low humidity value in the refrigerator compartment, so that increased drying can be achieved by throttling the circulation capacity. However, it is perfectly appropriate to use the fan 9 to be dimensioned in such a way that a desired air humidity can be achieved with a medium circulation capacity of the fan. This allows the heat exchange between the refrigerator compartment to be increased by increasing the circulation capacity beyond this average capacity 1 and evaporator 5 intensify, so that the duration of a start-up phase of the compressor 3 shortened and in this switch-on phase due to a relatively high temperature of the evaporator 5 the drying effect is weakened. This also makes it possible to control the humidity in the refrigerator compartment 1 targeted increase if this falls below a desired value.

Claims (11)

No-frost refrigerator with at least one storage compartment ( 1 ), one in one from the storage compartment ( 1 ) separate chamber ( 8th ) arranged, alternately switched on and off evaporator ( 5 ) and a fan ( 9 ) for circulating air between the storage compartment ( 1 ) and the chamber ( 8th ) of the evaporator ( 5 ), characterized in that an average circulation capacity of the fan ( 9 ) in an activated phase of the evaporator ( 5 ) is made variable. No-frost refrigerator according to claim 1, characterized in that the fan ( 9 ) in the switched on phase of the evaporator ( 5 ) can be switched off temporarily. No-frost refrigerator according to claim 2, characterized in that a control circuit ( 10 ) to control the operation of the evaporator ( 5 ) and the fan ( 9 ) is set up to switch on the evaporator ( 5 ) the fan ( 9 ) operate intermittently. No-frost refrigerator according to claim 3, characterized by a selector switch on which a pulse duty factor for the intermittent operation of the fan ( 9 ) is adjustable. No-frost refrigerator according to claim 3, characterized in that the control circuit ( 10 ) to at least one climate sensor ( 13 ) is coupled and the duty cycle as a function of at least one of the sensor ( 13 ) controls the climate parameters. No-frost refrigerator according to claim 1, characterized in that the fan ( 9 ) in the switched on phase of the evaporator ( 5 ) can be set to different non-disappearing speeds. No-frost refrigerator according to claim 6, characterized in that a control circuit ( 10 ) to control the operation of the evaporator ( 5 ) and the fan ( 9 ) is set up to switch on the evaporator ( 5 ) the fan ( 9 ) to operate at one of several selectable non-disappearing speeds. No-frost refrigerator according to claim 7, characterized by a selector switch, at which a speed for the operation of the fan is adjustable. No-frost refrigerator according to claim 7, characterized in that the control circuit ( 10 ) to at least one climate sensor ( 13 ) is coupled and the speed based on one of the sensor ( 13 ) regulates recorded climate parameters. Method for operating a refrigeration device according to one of the preceding claims, comprising the steps of: a) estimating a moisture value in the storage compartment ( 1 ); b) selecting a circulation capacity for the fan as a function of the estimated moisture value; c) operating the fan with the selected circulation capacity. A method according to claim 10, characterized in that the circulation rate chosen the lower becomes the higher the estimated Moisture value.