DE102012206806A1 - Single-circuit refrigeration unit and operating method for this - Google Patents

Abstract

A refrigerator, in particular household refrigerating appliance, comprises a compressor (7), an upstream and a downstream evaporator (5, 6) which are connected in series with the compressor (7), a first storage compartment (2), which is heated by the upstream evaporator (5). 5) and a second storage compartment (3) cooled by the downstream evaporator (6). A control unit (11) is arranged, in a normal cooling mode (S1-S5), to control the operation of the compressor (7) by comparing the temperature (Tnk) measured by a temperature sensor (13) in one of the storage compartments (3) with a first set value and is switchable from the normal cooling mode by a user to an intensive cooling mode having at least one phase of long compressor operating times ([t1, t2]; S6-S11) in which the control unit (11) controls the operation of the compressor (7) by comparison the measured temperature (Tnk) at a second setpoint lower than the first setpoint and comprising a phase of short compressor operating times ([t2, t3]; S12-S17) in which the compressor (7) switches between on and off the amount of refrigerant circulated after the subsequent turn-off is smaller than the capacity of the two liquid refrigerant evaporators (5, 6).

Description

The present invention relates to a refrigerator, in particular a domestic refrigerator, with a first and a second storage compartment, which are cooled by connected in series with a compressor evaporator, and an operating method for such a refrigerator.

In a refrigerator with evaporators connected in series, also referred to as a single-circuit refrigeration device, the refrigerant can circulate either only by both evaporators simultaneously when the compressor is operating, or by neither of the two evaporators when the compressor is not in operation. If such a refrigeration device conventionally has a temperature sensor on one of the storage compartments and a control unit switches the compressor on and off based on the temperature detected by this temperature sensor, there is the problem that when warm goods to be refrigerated are loaded into the storage compartment not monitored by the temperature sensor and is to be cooled therein, the control unit is unable to take this into account. The cooling of the newly invited refrigerated goods can therefore take a very long time, and the durability of existing refrigerated goods can be affected by this is heated by the newly loaded refrigerated goods. This problem is especially disturbing when the temperature sensorless storage compartment is a freezer compartment and the newly refrigerated goods to be frozen therein, since this a large amount of heat must be removed from the refrigerated goods.

A known technique for accelerating the freezing process in a single-circuit refrigerator is known as "super-operation". While in a normal refrigeration mode of the refrigeration appliance, the control unit turns the compressor on and off based on a comparison of temperature sensed by the temperature sensor with a user-settable setpoint temperature, it does so in the super-mode of operation by comparison with a fixed set temperature, which is generally much lower is the one set by the user. If the storage compartment where the temperature sensor is located is a standard cooling compartment, then the setpoint temperature in super cooling mode is generally just above the freezing point, so that a freezing of refrigerated goods in the normal compartment is just avoided.

The super cooling mode affects the energy efficiency of such a device, as inevitably both storage compartments are cooled down, even if only in the freezer compartment, a higher cooling capacity than normal is needed. In addition, the need to avoid undercooling and, in particular, freezing in the normal refrigeration compartment, necessitates regular interruptions of compressor operation, thus extending the time required to freeze newly refrigerated goods in the freezer compartment.

The object of the invention is to provide a refrigeration device and an operating method for this, which allow a fast and energy-efficient cooling of newly invited refrigerated goods.

The object is achieved on the one hand by a refrigerator, in particular a household refrigerator, with a compressor, an upstream and a downstream evaporator, which are connected in series with the compressor, a first storage compartment, which is cooled by the upstream evaporator, and a second storage compartment, which is cooled by the downstream evaporator, and a control unit, which is configured to control the operation of the compressor in a normal cooling mode based on a comparison of measured by a temperature sensor in one of the storage compartments temperature with a first setpoint and from the normal cooling mode by a user is switched to an intensive cooling mode, the intensive cooling mode is at least one phase of long compressor operating times, in which the control unit controls the operation of the compressor based on a comparison of the measured temperature with a second setpoint lower than the first setpoint t, and a phase of short compressor operating times, in which the amount of refrigerant circulated from the compressor between a switch-on and the subsequent switch-off is smaller than the capacity of the two liquid refrigerant evaporators.

Since the amount of liquid refrigerant in the phase of short operating times between a switching on and a switching off, i. in an operating phase of the compressor, enters the evaporator, although sufficient to fill the upstream evaporator, but not for the downstream, eliminates in this phase, a relatively large proportion of the cooling capacity of the compressor to the first storage compartment cooled by the upstream evaporator. The first storage compartment or newly stored refrigerated goods can therefore be cooled faster than by a conventional super operation, in which such a preference of the first storage compartment is not possible.

In order to selectively supply only the upstream evaporator with liquid refrigerant in a phase of short compressor run times, the amount of refrigerant circulated in the phase of short compressor operating times in each compressor operating time should correspond as closely as possible to the liquid refrigerant capacity of the upstream evaporator. The circulated refrigerant quantity should therefore be between 0.5 times and 1.5 times the capacity of the upstream evaporator.

If the volumetric capacity of the evaporator and the throughput of the compressor are known, the control unit can monitor the elapsed time since the last time the compressor was switched on and then switch the compressor off again when the desired amount of refrigerant has been established. Alternatively, it may be considered to use a temperature sensor located on one of the evaporators to monitor the advance of liquid refrigerant in the evaporators and to turn the compressor off again when cooling at the location of the temperature sensor indicates that the desired amount of refrigerant is circulating. Such a temperature sensor is desirably disposed in the vicinity of a refrigerant outlet of the upstream evaporator or a refrigerant inlet of the downstream evaporator.

Preferably, the control unit is set up to control a phase of long operating times and then a phase of short operating times when switching to the intensive cooling mode. Since both storage compartments are cooled in the long operating time phase, the short compressor runtimes phase in which essentially only the first storage compartment is cooled can subsequently be maintained for a long time without excessive heating of the second storage compartment.

The temperature sensor should expediently be arranged on the second storage compartment.

This makes it possible, in particular, for the control unit to start a phase of short compressor operating times when the temperature at the second storage compartment falls below a limit value.

Alternatively, a phase of short compressor operating times may also be started in each case after a predetermined duration of a phase of long compressor operating times.

Conveniently, the control unit should be set up to switch on the compressor at a predetermined time interval after switching to the intensive cooling mode. Thus, if a user knows in advance the time at which new refrigerated goods are to be loaded, by timely switching to the intensive refrigeration mode, when the new refrigerated goods are actually loaded, the compressor will start simultaneously and refrigeration power to freeze the new refrigerated goods thus immediately available.

A particularly rapid cooling of the new chilled goods can be achieved if, simultaneously with the switching on of the compressor, a phase of long compressor operating times also begins.

In practice, it is generally difficult to predict to the minute exactly when new refrigerated goods to be loaded will be ready. This can be accommodated by, if the refrigerator has a door and a door sensor for detecting an actuation of the door, the control unit does not turn on the compressor immediately after switching to the intensive cooling mode at the predetermined time interval, but initially only one time window opens, and the Compressor then turns on when an operation of the door is detected in the time window. Thus, the switching on of the compressor with the loading of the goods can be synchronized exactly, even if the time of the invitation is not exactly predictable.

The specified time interval should be several hours to ensure sufficient cooling before loading the new chilled goods. It is expedient if the predetermined time interval is an integer multiple of 24 hours; Deviations of up to +6 or -6 hours from this value may also be considered.

• a) in einem Normalkühlmodus Steuern des Betriebs des Verdichters anhand eines Vergleichs der von einem Temperaturfühler in einem der Lagerfächer gemessenen Temperatur mit einem ersten Sollwert;
• b) bei Erfassung einer Benutzereingabe, Umschalten in einen Intensivkühlmodus, der wenigstens eine Phase langer Verdichterbetriebszeiten, in der der Betrieb des Verdichters anhand eines Vergleichs der gemessenen Temperatur mit einem zweiten Sollwert gesteuert wird, der niedriger als der erste Sollwert ist, und eine Phase kurzer Verdichterbetriebszeiten umfasst, in der die vom Verdichter zwischen einem Einschalten und dem darauf folgenden Ausschalten umgewälzte Menge an Kältemittel kleiner ist als das Fassungsvermögen der beiden Verdampfer für flüssiges Kältemittel.

The invention also provides a method for controlling a compressor in a refrigerator, in which the compressor is connected in series with an upstream and a downstream evaporator, which cool a first or a second storage compartment, with the steps:

• a) in a normal cooling mode, controlling the operation of the compressor based on a comparison of the temperature measured by a temperature sensor in one of the storage compartments with a first set value;
• b) upon detection of a user input, switching to an intensive cooling mode, the at least one phase of long compressor operating times in which the operation of the compressor is controlled based on a comparison of the measured temperature with a second setpoint lower than the first setpoint and a phase shorter Compressor operating times in which the volume of refrigerant circulated from the compressor between a switch on and the subsequent shutdown is smaller than the capacity of the two evaporators for liquid refrigerant.

Further features and advantages of the invention will become apparent from the following description of embodiments with reference to the accompanying figures. From this description and the figures also show features of the embodiments, which are not in the claims are mentioned. Such features may also occur in combinations other than those specifically disclosed herein. Therefore, the fact that several such features are mentioned in the same sentence or in a different type of textual context does not justify the conclusion that they can occur only in the specific combination disclosed; instead, it is generally to be assumed that it is also possible to omit or modify individual ones of several such features, provided this does not call into question the functionality of the invention. Show it:

1 a schematic representation of a refrigeration device according to the invention;

2 the change of Verdichterbetriebs- and -nichtbetriebszeiten in a first embodiment of the refrigeration device;

3 a flowchart of a method of operation of a control circuit of the refrigerator.

1 schematically shows a single-circuit household refrigerator with a heat-insulating housing 1 whose interior is in two storage compartments, here a freezer 2 and a normal refrigerator 3 , is divided. The subdivision is here a wall 4 that like the subjects 2 . 3 surrounding walls of the housing 1 filled with insulating material; the two subjects 2 . 3 but could also be in a contiguous interior of the case 1 be formed or separated only by an air exchange between them obstructing wall.

Both subjects 2 . 3 is each an evaporator 5 respectively. 6 assigned. The evaporators 5 . 6 are shown here as a coldwall evaporator, but there are also other types of evaporators into consideration. The evaporators 5 . 6 can be on separate boards or even on a single wall 4 bridging over both partitions 2 . 3 be formed extending board.

The evaporators 5 . 6 are part of a refrigerant circuit, which also in a conventional manner a compressor 7 , for example, on a rear wall of the housing 1 attached liquefier 8th , a dryer 9 and a capillary 10 includes. Refrigerant in the compressor 7 has been condensed and heated, gives its heat to the condenser 8th and condenses. The liquid refrigerant relaxes as it passes through the capillary 10 and reached from there first the evaporator 5 of the freezer, where it can evaporate under low pressure. The evaporator 6 closes downstream on the evaporator 5 on, and its output is connected to a suction port of the compressor 7 connected.

A control circuit 11 Used to turn the compressor on and off based on temperature readings from an evaporator temperature sensor 12 and an air temperature sensor 13 to be delivered. The evaporator temperature sensor 12 is in close thermal contact with the evaporator 6 , preferably on the circuit board of the evaporator 6 , assembled.

The evaporator temperature sensor 12 should be on the evaporator 6 adjacent to an upstream portion of the on the evaporator 6 extending refrigerant line should be arranged to react quickly when fresh low-temperature refrigerant from the evaporator 5 in the evaporator 6 forced out. It is also expedient to attach the evaporator temperature sensor 12 in the lower part of the evaporator 6 , so that the temperature sensor 12 during a defrosting operation can provide reliable information about the remnants of the remains that build up during defrosting at the bottom of the evaporator 6 collects. The in 1 Construction shown meets these two requirements at the same time by the refrigerant piping on the evaporator 6 from a refrigerant inlet 14 at the upper edge, first down a direct path to the lower corner of the evaporator 6 runs, in which also the evaporator temperature sensor 12 is attached, and then meandering across the surface of the evaporator 6 spreads.

The measured value of the air temperature sensor 13 should as accurately as possible the air temperature in the normal refrigeration compartment 3 play. For this purpose, the air temperature sensor 13 in a wall of the housing 1 between their insulation material filling and a normal cooling compartment 3 delimiting inner container removed from the evaporator 6 arranged.

The subjects 2 . 3 each have an interior light, not shown here, which is turned on and off by a switch actuated in a conventional manner by the door of the compartment. From these two switches shows 1 just the one with 16 designated switch of the freezer compartment 2 ,

A user interface of the refrigeration device includes one with the control circuit 11 connected operating mode selector switch 17 , The operating mode selector switch 17 at least serves to switch from a normal cooling mode to an intensive cooling mode. It is possible to switch back from intensive to normal cooling mode by pressing the operating mode selector switch again 17 or time-controlled, after expiration of a maximum permissible duration of the intensive cooling mode.

2 shows an example of the operating state, on or off, of the compressor 7 over time in the normal cooling mode and in the Intensive cooling mode. At time t0, the refrigeration device is in the normal cooling mode. A set temperature of the normal cooling compartment 3 is adjustable in a conventional manner to a controller of the user interface by the user. The control circuit 11 switches the compressor 7 always when the temperature sensor 13 recorded air temperature Tnk in the normal refrigerated compartment 3 exceeds a switch-on threshold Tein, which corresponds to the setpoint temperature plus a small tolerance value, and switches it off again as soon as a switch-off threshold Taus which lies below the setpoint temperature by a predetermined amount is undershot. This results in switch-on phases Δt1 of medium duration, which alternate with relatively long switch-off phases Δt0.

If the user at time t1 by pressing the operating mode selector switch 17 in the intensive cooling mode, this initially results in the control circuit 11 no longer uses the on and off thresholds Tein, Taus derived from the setpoint temperature set by the user on the controller, but switches on and off thresholds Tein ', Taus', which are derived in a corresponding manner from a considerably lower temperature specified by the manufacturer of the device. In practice, in particular a switch-off threshold Taus' is used, which is only so far above 0 ° C, as necessary, to a local underrun of the freezing point in the normal refrigeration compartment 3 to avoid. That is, the closer to the evaporator 6 of the standard refrigerator compartment 3 the temperature sensor 13 is arranged, the closer to the freezing point, Taus' can be selected.

By lowering the on and off thresholds arise - especially shortly after switching to the intensive cooling mode, when the normal refrigeration compartment 3 Overall, even much warmer than the low turn-off threshold Taus', compared to the normal mode of operation significantly longer switch-on Δt1 'and shorter switch-off Δt0', and both subjects 2 . 3 are cooled quickly.

This effect slows down when the local average of the temperature of the standard refrigerator compartment 3 the deep turn-off threshold Taus' approaches. The reason for this is that the normal fridge 3 Homogeneously cooled over time. While in an initial phase of the intensive cooling mode of the evaporator 6 seen beyond the temperature sensor 13 lying region of the normal refrigeration compartment is still substantially at the set temperature set by the user and in a downtime of the compressor heat from this area quickly to the temperature sensor 13 and in between the temperature sensor 13 and the evaporator 6 lying area of the normal refrigeration compartment 3 spreads, takes in the course of several compressor operating times of the temperature gradient in the normal refrigeration compartment 3 Gradually, so that the downtime of the compressor longer and the operating times are shorter. This in turn prevents intensive cooling of the freezer compartment 2 ,

Nevertheless, sufficient for quick freezing of newly invited refrigerated goods sufficient cooling capacity in the freezer 2 to be able to provide, goes the control circuit 11 in the context of the intensive cooling mode at a time t2 over in a phase of short compressor operating times. For this purpose, the compressor 7 at time t2, first for a time Δt0 "off, whose length is such that it evaporates in the evaporator 5 of the freezer compartment 2 available liquid refrigerant is sufficient. Then the compressor goes 7 for a period Δt1 "in operation, whose length is time-controlled or by the temperature sensor 12 can be controlled. In the case of timing, the compressor will 7 operated as long as it is aware of the throughput of the compressor 7 and the capacity of the evaporator 5 required to remove the refrigerant vapor from the evaporator 5 in the evaporator 6 to displace and the evaporator 5 to be filled with fresh, liquid refrigerant. In case of control by means of the temperature sensor 12 becomes the compressor 7 operated until a temperature drop at the temperature sensor 12 indicating that liquid refrigerant is above the evaporator 5 to the temperature sensor 12 has penetrated.

In one case as in the other case, practically only the evaporator 5 of the freezer compartment 2 supplied with liquid refrigerant, whereas in the evaporator 6 only refrigerant vapor arrives. In this way, the freezer 2 with high performance further cooled while on the normal refrigeration compartment 3 virtually no cooling capacity is eliminated. The resulting over time heating of the normal refrigeration compartment 3 can be tolerated, since this is colder anyway, as the set temperature set by the user corresponds; a heating of the normal refrigeration compartment 3 It is even desirable as it comes out after a few hours, at a time t3, when the temperature in the normal refrigeration compartment 3 has returned to the vicinity of the set by the user set temperature, a return to the control of the compressor based on the predetermined low thresholds Taus ', Tein' allows.

3 shows a flowchart of a working method of the control circuit 11 according to a further developed embodiment of the invention. At the beginning of the method, the method is in the normal cooling mode: In step S1, it is checked whether the temperature Tnk of the temperature sensor 13 is above the switch-on threshold Tein, and if so, in step S2 the compressor 7 switched on. If not, it is checked in step S3 whether the temperature Tnk is below the switch-off threshold Toff, and if so, the compressor becomes 7 switched off in step S4. Step S5 checks whether a user input, in particular an operation of the mode selector switch 17 , is present. If this is not the case, the method returns to the output. Thus, steps S1-S5 are repeated in an endless loop as long as the normal cooling mode continues.

The user of the refrigerator is stopped, if he wants to re-store and freeze a larger amount of fresh refrigerated goods, in good time before, at a time interval D from the intended time of storage, to activate the intensive cooling mode. The time interval D can be in particular 24 h or an integer multiple thereof.

If the intensive cooling mode has been activated at time t1, the control circuit sets a timer in step S6. This is followed by a comparison S7 of the temperature Tnk with a predetermined low switch-on threshold Tein 'and, if this switch-on threshold is exceeded, the switch-on S8 of the compressor. In step S9, it is checked whether a predetermined low turn-off threshold Taus' is exceeded, and if so, in step S10 of the compressor 7 switched off again. In step S11 it is checked whether a predetermined period of time d has elapsed since the start S6 of the timer. The time span d is D - n (Δt0 "+ Δt1") - Δt0 ", where n is a natural number and n (Δt0" + Δt1 ") should be several hours. If this time has not yet elapsed, the process returns to step S6.

Otherwise, the compressor will 7 (if it is not already turned off at the time of the check S11) is turned off in step S12, the lapse of a turn-off time Δt0 "is waited for (S13), the compressor is turned on in step S14, and the lapse of the turn-on time Δt1" is awaited (S15) , The steps S12 to S15 are cyclically repeated until it is determined in step S17 that the predetermined period of time D has elapsed since the start of the timer in step S6. Due to the above definition of the period of time, the end of the period D always coincides with the end of a turn-off time.

If the time period D has elapsed, the process returns to step S7 to refrigerated goods, which is assumed to be in the freezer at exactly this time 2 has been charged to freeze quickly.

If, since the start of the timer, a time which is likely to be sufficient for freezing the chilled goods, e.g. 48 hours elapsed, then this is detected in step S16 and causes the process to return to normal operation S8.

According to one variant, it can be provided that, after the time period D has elapsed, step S17 does not unconditionally return to step S7, but that a time window is opened whose duration is preferably not greater than Δt0 "+ Δt1", and in that time window control circuit 11 a signal from the switch 16 waits for a user to access the freezer 2 displays. When this signal arrives, it can be concluded that in fact new refrigerated goods have been stored, and the control circuit 11 responds by jumping to step S7. Thus, the start of the compressor and the invitation of the item to be chilled are exactly synchronized. The window of time passes without the switch 16 indicates a door operation, then the method also returns to step S7 to keep the compartments of the refrigerator cold in the event that, although later than intended, still new goods to be refrigerated is invited.

If the late loading occurs while the control circuit repeats the steps S12 to S15 in a loop, it may be provided that the door operation triggers a jump to step S7.

Claims (11)

Refrigerating appliance, in particular household refrigerating appliance, with a compressor ( 7 ), an upstream and a downstream evaporator ( 5 . 6 ) connected in series with the compressor ( 7 ), a first storage compartment ( 2 ) passing through the upstream evaporator ( 5 ) and a second storage compartment ( 3 ) passing through the downstream evaporator ( 6 ) is cooled, and a control unit ( 11 ) arranged to operate the compressor in a normal cooling mode (S1-S5) ( 7 ) based on a comparison of that of a temperature sensor ( 13 ) in one of the storage compartments ( 3 ) is controlled with a first setpoint value and can be switched from the normal cooling mode by a user into an intensive cooling mode, characterized in that the intensive cooling mode has at least one phase of long compressor operating times ([t1, t2]; S6-S11) in which the control unit ( 11 ) the operation of the compressor ( 7 ) based on a comparison of the measured temperature (Tnk) with a second setpoint lower than the first setpoint, and a phase of short compressor operating times ([t2, t3]; S12-S17) in which the compressor ( 7 ) is less than the capacity of the two evaporators between switching on and the subsequent switching off 5 . 6 ) for liquid refrigerant. Refrigerating appliance according to claim 1, characterized in that in the phase of short compressor operating times ([t2, t3], S12-S17) between a Switching on and then switching off the compressor ( 7 ) recirculated amount of refrigerant between 0.5 times and 1.5 times the liquid refrigerant capacity of the upstream evaporator ( 5 ) is. Refrigerating appliance according to claim 1 or 2, characterized in that the control unit ( 11 ) is set to control first a phase of long compressor operating times ([t1, t2], S6-11) and then a phase of short compressor operating times ([t2, t3], S12-S17) when switching to the intensive cooling mode. Refrigerating appliance according to one of the preceding claims, characterized in that the temperature sensor ( 13 ) at the second storage compartment ( 3 ) is arranged. Refrigerating appliance according to claim 4, characterized in that the control unit ( 11 ) is arranged to start a phase of short compressor operating times when the temperature at the second storage compartment falls below a threshold value. Refrigerating appliance according to claim 3 or 4, characterized in that the control unit is set up after a predetermined duration of a phase of long compressor operating times ([t1, t2]; S6-S11) a phase of short compressor operating times ([t2, t3]; S12-S17) to start. Refrigerating appliance according to one of the preceding claims, characterized in that the control unit ( 11 ) is set up at a predetermined time interval from the switching (t2; S6) into the intensive cooling mode the compressor ( 11 ). Refrigerating appliance according to one of claims 1 to 6, characterized in that it has a door and a door sensor ( 16 ) for detecting an actuation of the door and the control unit ( 11 ) is set up to define a time window at a predetermined time interval from the switchover (t2; S6) into the intensive cooling mode and to connect the compressor ( 7 ) when an operation of the door is detected in the time window. Refrigerating appliance according to claim 7 or 8, characterized in that the control unit ( 11 ) is arranged to start a phase of long compressor operating times ([t3, ...]; S6-S11) at the predetermined time interval after switching over. Refrigerating appliance according to claim 7, 8 or 9, characterized in that the predetermined time interval deviates by a maximum of + 6h or -6h from an integer multiple of 24 h. Method for controlling a compressor in a refrigerator, in which the compressor is equipped with an upstream and a downstream evaporator ( 5 . 6 ) is connected in series, the first and a second storage compartment ( 2 . 3 ), comprising the steps of: a) in a normal cooling mode (S1-S5) controlling the operation of the compressor ( 7 ) based on a comparison of that of a temperature sensor ( 13 ) in one of the storage compartments ( 3 ) measured temperature (Tnk) with a first setpoint value; b) upon detection of a user input (S5), switching to an intensive cooling mode (S6-S17), the at least one phase ([t1, t2], S6-S11) of long compressor operating times (Δt1 ') in which the operation of the compressor ( 7 ) is controlled based on a comparison of the measured temperature (Tnk) with a second setpoint lower than the first setpoint, and a phase ([t2, t3]; S12-S17) of short compressor operating times (Δt1 ") in which the from the compressor ( 7 ) is less than the capacity of the two evaporators between switching on and the subsequent switching off 5 . 6 ) for liquid refrigerant.

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