EP2458310A2 - Method for operating a fridge and/or freezer and fridge and/or freezer - Google Patents

Abstract

The method involves operating a refrigeration unit at two different high and low power levels. The duration of running time and/or standing time of the refrigeration unit is varied according to the characteristic of energy with which the refrigeration unit is operated. The operation of the refrigeration unit is constantly monitored at each stage. An independent claim is included for cooling and/or freezing apparatus.

Description

The invention relates to a method for operating a refrigerator and / or freezer. The invention further relates to a refrigerator and / or freezer.

In the recent past, the power supply has become established as a result of the shift to decentralized supply and the increased technical possibilities for communicative networking between different electricity network participants (producers, consumers, etc.). This type of communicative networking is referred to as an "intelligent power grid" or "smart grid". A feature of the smart grid is that a consumer can select characteristics of the supplied current such as the price of electricity or the CO ₂ balance, the type of power generation and the like within certain limits.

In the prior art refrigeration units for refrigerators and / or freezers, such as variable speed compressors are known, which can be operated as needed with different power. On a moderate power level, a very good energy efficiency can be achieved. At the same time, increasing the power makes it possible to obtain a larger cooling capacity at a slightly lower efficiency.

Object of the present invention is to improve the energy efficiency of a refrigerator and / or freezer.

This object is achieved by a method according to claim 1. Advantageous embodiments emerge from the subclaims.

Accordingly, a method for operating a refrigerator and / or freezer with at least one refrigeration unit is provided, wherein the refrigeration unit is selectively operable or operated on one of at least two different power levels. According to the invention, the method is characterized in that the duration of a running time and / or an idle time of the refrigeration unit is changed as a function of a characteristic of the energy with which the refrigerating unit is operated.

Thus, the choice between different power levels of the refrigeration unit can be used when connecting the refrigerator and / or freezer to a smart grid for the most efficient operation of the refrigerator and / or freezer, which, for example, a cost savings can be achieved or other optimizations are possible.

The operation of a refrigerator and / or freezer using a method according to the invention is hereinafter referred to as "smart grid mode" operation.

The term "switch-on condition" or "switch-off condition" used below stands for threshold values of a device-specific measured variable, such as, for example, the temperature of the cooled interior or the evaporator temperature. In the presence of the switch-on condition, the refrigeration unit can be switched on or an operating cycle or an operating mode of the refrigeration unit can be started. If the switch-off condition is met, the refrigeration unit can switched off or an operating cycle or an operating mode of the refrigeration unit are terminated.

The term "operating cycle" used hereinafter refers to the operation of the refrigeration unit between the presence of a switch-on condition and the subsequent achievement of a switch-off condition. It can correspond to the total running time of the compressor or the running time of the compressor between two idle times.

In one embodiment, the refrigeration unit is operated with an input power stage in the presence of a turn-on condition. Optionally, the refrigeration unit is activated in the presence of the switch-on condition after the idle time.

In one embodiment, when a turn-off condition is not achieved, the refrigeration unit is operated within a time interval with a follow-up power stage. The transition to a subsequent power stage occurs within an operating cycle of the refrigeration unit and may be due to the fact that the switch-off condition is not reached or prematurely within the time interval. The follow-up level may be higher or lower, i. correspond with a higher or lower cooling capacity.

In one embodiment, the refrigeration unit is selectively operable on one of at least three, four or n different power levels, where n is an integer ≥ 2. The term "power level" is not to be understood as limiting discrete levels, but also includes a continuous power spectrum.

The characteristic of the energy is preferably obtained from a smart grid. Suitable characteristics include the (current) electricity tariff or electricity price, the (current) network utilization, the CO ₂ balance of the supplied electricity, the environmental balance of the supplied electricity, the availability of locally stored electricity, the degree of filling of storage, the Power source, whether it is electricity generated in the home, and the like.

In one embodiment, the duration of a running time is changed until the switching of the refrigeration unit from one power level to a higher or lower power level as a function of the characteristic of the energy, preferably lengthened or shortened.

In one embodiment, the duration of a running time is changed until the refrigeration unit is switched off as a function of the characteristic of the energy, preferably lengthened or shortened.

In one embodiment, the duration of a standstill time until the refrigeration unit is switched on is changed depending on the characteristic of the energy, preferably lengthened or shortened.

These changes cause a dynamic shift of running times and / or downtime of the refrigeration unit in response to a characteristic of the energy, preferably from an external source. The changes in the transit times and / or idle times can take place independently of reaching a switch-on condition and / or a switch-off condition.

In one embodiment, the duration of the runtime and / or idle time is extended or shortened by addition or subtraction of a fixed or variable time. The shortening or extension of the transit time and standing time is preferably between about -60 minutes and about +720 minutes, and more preferably between about -40 minutes and about +240 minutes. The added time or the allowed time window for an extension and / or shortening of the transit time and / or idle time can be different for each switching from one power level to a higher or lower power level or depending on the current power and optionally set in the parameter set of the device.

In one embodiment, a status bit is set in response to the power signal. The duration of a runtime and / or an idle time of the refrigeration unit can be changed depending on the status bit. For example, a status bit is given the value 0 or 1. For example, the status bit can be set to 0 or 1 in response to a low or high power tariff.

In one embodiment, the performance may be kept low or prematurely lowered for a disadvantageous characteristic, such as a high current rate. In one embodiment, the power may be maintained high or increased prematurely for a positive characteristic, such as a low power tariff.

In one embodiment, a power stage has better efficiency and lower absolute cooling power compared to a higher power stage. A higher power level can have both a higher cooling capacity and a higher power consumption. The power consumption may increase more than the cooling capacity or disproportionate to the cooling capacity at a power increase. The efficiency is defined as the achieved cooling capacity per required energy unit.

It is advantageous that the advantage drawn by a good characteristic, for example the cost savings, at least compensates and preferably overcompensates for the increased consumption of the device per generated refrigeration unit with a higher power of the refrigeration unit.

In one embodiment, the power of the refrigeration unit may be continuously changed. The duration of a time to switch the refrigeration unit from a power stage to a higher or lower power level in this embodiment may correspond to a delay in the power increase or decrease at a specific power threshold or a lingering in a certain power range. The change in the duration of a term and / or an idle time of the refrigeration unit may correspond to the introduction or deletion or lengthening or shortening of such a delay or dwell time. In one embodiment, the power of the refrigeration unit may be changed stepwise.

In one embodiment, the dependence of the duration of the duration and / or the idle time on the characteristic of the energy can be switched on and / or switched off. The switching on or off can be done automatically and / or manually, and during or outside of an operating cycle.

The refrigerator and / or freezer should at all times be in a position to provide the refrigeration capacity required by the user by entering commands or by his behavior. As soon as a device-specific measured value such as, for example, the internal temperature of a refrigerator or freezer compartment and / or a calculated value derived from the measured value or values deviates from a default value, for example a temperature selected by the customer, or is outside a tolerance range, the smart grid mode is preferably deactivated automatically and a conventional power control of the device may be used. If the deviation is no longer present, the smart grid mode can preferably be automatically re-activated. An automatic deactivation of the smart grid mode can be done, for example, when the device electronics detects that the cooling specifications can not be achieved with the operation in the smart grid mode. The implementation of an early detection for the deviation from a default value and the early change in the power control without smart grid mode can be provided in a method according to the invention.

In one embodiment, a limit power level may be set for the operation of the refrigeration unit, which does not correspond to the highest or lowest possible power level of the refrigeration unit. By defining an upper limit power level, for example, a high noise level and / or a poor efficiency of the device can be avoided. For example, a limit power level can be set so that the operation of the refrigeration unit below this limit, the efficiency of the refrigeration unit is sufficient and cooling capacities are connected above this limit with a lower efficiency. If appropriate, this restriction is only applied if it does not prevent a refrigeration event, such as insufficient cooling despite operation over a time interval at the marginal power stage.

In one embodiment, switching from the second highest to the highest power level may be delayed. Using continuous-rate chillers, the power increase and / or decrease may be delayed once the power reaches a certain threshold. Suitable thresholds include, for example, about 20% of the maximum power as the lower limit power level and about 70% of the maximum power as the upper limit power level.

In one embodiment, multiple limit power levels and / or thresholds may be provided.

In one embodiment, furthermore, a switch-on condition and / or a switch-off condition can be changed depending on the characteristic of the energy, in particular lowered and / or increased by addition of offset values. This provides an additional way of dynamically controlling power consumption. For example, the switch-on temperature can be reduced at a low electricity tariff, so that a quick restart of the compressor is achieved.

In one embodiment, a change in a switch-on condition and / or switch-off condition can be reversed if the operation of the refrigeration unit is beyond a limit power stage to achieve this changed switch-on condition and / or switch-off condition. The switch-on condition and / or switch-off condition can be reset to the original status or the series status.

In one embodiment, runtimes and / or idle times and / or status bits and / or turn-on conditions and / or turn-off conditions are determined externally, for example in an external controller, and are then sent to the device electronics.

The invention further relates to a refrigerator and / or freezer according to claim 13. Advantageous embodiments will become apparent from the dependent claims.

Accordingly, a refrigerator and / or freezer is provided with at least one refrigeration unit and at least one internal or external control and / or regulating unit. The control and / or regulating unit and the refrigeration unit are connected or connectable to one another in such a way that the refrigeration unit can be controlled or activated by the control and / or regulating unit. The refrigeration unit should optionally be operable or operated on one of at least two different power levels. According to the invention, the cooling and / or freezing appliance is characterized in that a control algorithm is stored on the control and / or regulating unit, which specifies a method according to the invention for the operation of the refrigeration unit.

The control algorithm may define power levels and / or run times and / or idle times and / or turn-on conditions and / or turn-off conditions for the operation of the refrigeration unit. By changing the control algorithm, a change of these variables can be implemented. Furthermore, in the control and / or regulating unit, a status bit can be set in response to an external energy signal.

In the case of an internal control and / or regulating unit, the control and / or regulating unit may be part of the device electronics.

In the case of an external control and / or regulating unit, the control and / or regulating unit may represent an external extension of the device. An external control and / or regulating unit may be connected to the device electronics via a wireless and / or wired data line or via a communication module.

In an embodiment, the control unit has a wireless and / or wired data interface or a communication module. Via this data interface, an energy signal and / or a status bit can be obtained from a server or the like and / or the control and / or regulating unit can communicate with a smart grid via this data interface.

Suitable wired data interfaces include, for example, PLC, EIB, KNX, EEBus and the like. Suitable wireless data interfaces include, for example, WLAN, WiFi, Powerline, Bluetooth, Bus, GSM, ZigBee, and the like.

In one embodiment, the refrigeration unit includes a variable speed compressor, such as a variable speed compressor. The compressor may be part of a conventional refrigerant circuit for refrigerators and / or freezers, which has an evaporator, a condenser and a throttle. Thus, the refrigerator and / or freezer according to the invention can be designed with such a refrigerant circuit. The different power levels of the refrigeration unit may differ by different compressor speeds. Suitable compressors include conventional compressors with reciprocating or linear compressors.

However, the invention is not limited to variable speed compressors. Alternatively, refrigeration units with magnetic or thermoacoustic coolers or also possible future technologies are included.

In one embodiment, device-specific measured values, such as, for example, the temperature in the interior of the device are monitored with one or more temperature sensors.

In one embodiment, the refrigerator and / or freezer according to the invention is a household appliance or even a commercial appliance.

Figur 1:

ein P(t) und ein T(t) Diagramm für den Betrieb eines drehzahlgeregelten Kompressors gemäß dem Stand der Technik,

Figur 2:

ein Beispiel für das P(t) Diagramm aus Figur 1 nach Modifikation im Smart Grid Modus bei günstigem Charakteristikum der Energie, und

Figur 3:

ein Beispiel für das P(t) Diagramm aus Figur 1 nach Modifikation im Smart Grid Modus bei ungünstigem Charakteristikum der Energie.

Further details and advantages of the invention will become apparent from the figures and embodiments described below. In the figures show:

FIG. 1:

a P (t) and a T (t) diagram for the operation of a variable speed compressor according to the prior art,

FIG. 2:

an example of the P (t) diagram FIG. 1 after modification in the Smart Grid mode with favorable characteristic of the energy, and

FIG. 3:

an example of the P (t) diagram FIG. 1 after modification in Smart Grid mode with unfavorable characteristic of the energy.

A household refrigerator has an internal temperature sensor, a variable speed compressor and a control unit.

The control unit communicates with both the indoor temperature sensor and the compressor. In addition, the control unit has a wireless interface via which energy characteristics can be received from the smart grid.

At a low compressor speed, the compressor has good energy efficiency and low noise emission. By increasing the speed, it is possible to call up an increasing absolute cooling capacity with decreasing energy efficiency, which may be accompanied by an increasing noise emission. For example, the variable speed compressor can operate at four defined power levels operate. It is of course a non-limiting example of the invention.

Two operating modes are available for the refrigerator: Operation without Smart Grid mode and operation in Smart Grid mode. The user can manually choose between the two modes. Alternatively or additionally, the device can automatically switch between the two modes if the cooling specifications in Smart Grid mode can not be met.

• Das gewünschte Innentemperaturfenster des Kühlraumes liegt zwischen T_E (der Einschalttemperatur oder -bedingung) und T_A (der Ausschalttemperatur oder -bedingung). Die Innentemperatur wird mit Hilfe eines Temperaturfühlers überwacht. In der Stehzeit des Kompressors steigt die Innentemperatur durch Wärmeeintrag in den Kühlraum an. Sobald die Innentemperatur zum Zeitpunkt t₀ die obere Temperaturgrenze T_E erreicht, wird der Kompressor mit einer Eingangsleistungsstufe in Betrieb genommen. Der Betrieb des Kompressors erfolgt zunächst auf einer geringen Leistungsstufe mit der Leistung L₁. Der Zeitpunkt t₀ wird auch als Einschaltzeitpunkt bezeichnet.

In operation without Smart Grid mode, the control of the compressor is carried out by the control unit in accordance with a defined scheme, which in FIG. 1 is represented by a P (t) and a T (t) diagram:

• The desired interior temperature window of the cold room is between T _E (the turn-on temperature or condition) and T _A (the turn-off temperature or condition). The internal temperature is monitored by means of a temperature sensor. During the standstill of the compressor, the internal temperature rises due to heat input into the cold room. As soon as the internal temperature reaches the upper temperature limit T _E at time t ₀ , the compressor is put into operation with an input power stage. The operation of the compressor initially takes place at a low power level with the power L ₁ . The time t ₀ is also called the switch-on time.

When operating the compressor with the power L ₁ , the internal temperature in the cold room slowly decreases. For the operation of the compressor at the power level L ₁ , a specific time interval Δt (1 → 2) is provided in the algorithm.

If the lower temperature limit T _{A is reached} within this first time interval Δt (1 → 2) (in FIG. 1 not shown), the compressor is turned off and the operating cycle of the compressor ends. For the sake of simplicity, the switch-off condition here corresponds to the lower limit and the switch-on condition of the upper limit for the internal temperature of the cold room. The switch-off condition However, in practice, a higher temperature and the turn-on condition may be a lower temperature to account for any delayed response.

If the lower temperature limit T _{A is} not reached within this first time interval Δt (1 → 2) (in FIG FIG. 1 shown), the power of the refrigeration unit at a time t ₁ (switching time) is increased and operated the refrigeration unit at a higher power level with the power L ₂ . When operating the compressor with the power L ₂ , the internal temperature in the refrigerator sinks faster than during operation of the compressor with the power L _1. For the operation of the compressor at the power level L ₂ in the algorithm again a specific time interval .DELTA.t (2 → 3 ) intended. This time interval Δt (2 → 3) may correspond to the time interval Δt (1 → 2) or may differ therefrom, ie be shorter or longer.

If the lower temperature limit T _A within this second time interval .DELTA.t (2 → 3) is reached (in FIG. 1 not shown), the compressor is turned off and the operating cycle of the compressor ends.

If the lower temperature limit T _{A is} not reached again within this second time interval Δt (2 _→ 3) (in FIG FIG. 1 shown), the power of the refrigeration unit at a time t ₂ (another switching time) is increased and the refrigeration unit operated on a turn higher power level with the power L ₃ . When operating the compressor with the power L ₃ , the internal temperature in the refrigerator sinks even faster than when operating the compressor with the power L ₂ . For the operation of the compressor on the power level L ₃ , a specific time interval Δt (3 → 4) is again provided in the algorithm. This time interval Δt (3 → 4) may correspond to other time intervals such as Δt (1-72) or Δt (2 _→ 3) or may differ therefrom, ie be shorter or longer.

If the lower temperature limit T _{A is reached} within this third time interval Δt (3 → 4) (in FIG FIG. 1 shown), the compressor is turned off and the operating cycle Δt (T _E → T _A ) of the compressor ends. The time t ₃ is also referred to as the switch-off time.

Subsequently, the cold room is heated in the dwell time .DELTA.t _{s of} the compressor by heat input until the start condition T _E is reached again, before a new (follow) operating cycle begins at the switch-on time t ₀ '.

Typically, the input power stage of the sequential duty cycle is the last (final) power stage of the previous operating cycle. In the example shown, this would correspond to the power level L ₃ .

In the algorithm, however, it may be provided that the power stage (input power stage of the subsequent duty cycle) is lowered (as in FIG FIG. 1 shown) when the time required until reaching the switch-off condition when operating with the final power level L ₃ falls below a certain duration. This duration can be read in the figure as the difference between condition time t _x and switching time t ₂ . In the illustrated case, the switch-off time t _{3 is} before the conditional time t _x , so that the input power stage of the next operating cycle is reduced compared to the final power stage of the previous operating cycle, in the illustrated case from L ₃ to L ₂ .

When the superfrost function is activated, the compressor can be operated immediately at the highest speed.

In Smart Grid mode, the control of the variable speed compressor from the control unit is dynamic and changeable to allow more efficient operation in the Smart Grid. FIGS. 2 and 3 show examples of the P (t) diagram FIG. 1 after modification according to a current characteristic in the Smart Grid mode.

First, the control unit acquires a current characteristic via the wireless interface and outputs a status bit 0 or 1 based on the power signal.

FIG. 2 shows the P (t) diagram FIG. 1 which has been modified in smart grid mode according to a status bit that corresponds to a favorable energy characteristic such as a favorable electricity price. The original P (t) history FIG. 1 is shown with a solid line. The modified P (t) curve according to Smart Grid mode is shown with a dotted line.

In connection with the description of FIG. 1 Illustrations shown apply to the description of FIG. 2 corresponding.

Deviating from this, the first time interval Δt (1 → 2) is shortened and the compressor is already operated at an earlier time with a higher power level L ₂ . As a result, the internal temperature of the refrigerator and / or freezer decreases faster than during operation according to FIG. 1 , The device works here with a lower energy efficiency by using higher compressor speeds, but this is overcompensated by the present, low electricity price. In this case, despite the poorer energy efficiency equal to the higher power level is chosen because the system in the Smart Grid mode to achieve as much cooling power using low energy. The first time interval .DELTA.t (1 → 2) may also be shortened to 0, which would mean that the compressor would be operated equal to the second power level L ₂ .

Further, in FIG. 2 a shortening of the downtime of the compressor can be shortened in the presence of cheap electricity. The operation of the compressor starts earlier, although the switch-on condition has not yet been reached. However, the interior can be cooled by utilizing cheap electricity, and the same cooling capacity does not have to be provided at a later time while consuming possibly more expensive electricity.

The cooling cycle is in FIG. 2 already completed just after the time t ₁ , so that the available cheap. Energy was used optimally.

FIG. 3 shows the P (t) diagram FIG. 1 which has been modified in smart grid mode according to a status bit corresponding to an unfavorable energy characteristic such as an expensive electricity price. The original P (t) history FIG. 1 is shown with a solid line. The modified P (t) curve according to Smart Grid mode is shown with a dotted line.

In connection with the description of FIG. 1 Illustrations shown apply to the description of FIG. 3 corresponding.

Deviating from this, the first time interval Δt (1 → 2) is extended and the compressor is operated at a later time with a higher power level L ₂ . As a result, the internal temperature of the refrigerator and / or freezer decreases slower than during operation FIG. 1 However, the device works with better energy efficiency. The lack of cooling capacity compared to the operation according to FIG. 1 may be provided at a later date, using cheap electricity.

The cooling takes longer than during operation according to FIG. 1 , However, the power consumption for achieving the same cooling performance is lower due to the better energy efficiency. The third power level L ₃ is not used here.

In summary, it follows that with a method according to the invention and a refrigerator and / or freezer according to the invention the energy and / or cost efficiency can be significantly increased by interaction with an intelligent power grid.

Claims (15)

Method for operating a refrigerator and / or freezer with at least one refrigeration unit that can be operated on at least two different power levels,
characterized,
that the duration at least of the refrigeration unit is operated a characteristic of the energy is changed at least one transit time and / or at least one standing time of the refrigeration unit in dependence. A method according to claim 1, characterized in that the duration of a running time is reduced or extended until switching of the refrigeration unit from a power level to a higher or lower power level depending on the characteristic of the energy. Method according to one of the preceding claims, characterized in that the duration of a running time is shortened or extended until the refrigeration unit is switched off as a function of the characteristic of the energy. Method according to one of the preceding claims, characterized in that the duration of a standstill time until the refrigeration unit is switched on is shortened or lengthened as a function of the characteristic of the energy. Method according to one of the preceding claims, characterized in that the duration of the running time and / or retention time of the refrigeration unit is extended or shortened by adding a fixed predetermined or variable additional time. Method according to one of the preceding claims, characterized in that a status bit is set depending on the characteristic of the energy and the duration of the running time and / or the idle time of the refrigeration unit is shortened or lengthened as a function of the status bit. Method according to one of the preceding claims, characterized in that a power stage compared to a higher power level has a better efficiency and a lower absolute cooling capacity. Method according to one of the preceding claims, characterized in that the power of the refrigeration unit is changed continuously or stepwise. Method according to one of the preceding claims, characterized in that the dependence of the duration of the running time and / or standing time from Value of the characteristic of the energy and / or status bits automatically and / or manually switched on and / or off. Method according to one of the preceding claims, characterized in that for the operation of the refrigeration unit, a limit power level is set, which does not correspond to the highest or lowest possible power level of the refrigeration unit. Method according to one of the preceding claims, characterized in that further a switch-on condition and / or a switch-off condition is changed depending on the characteristic of the energy. A method according to claims 10 and 11, characterized in that the change of a condition is reversed, if the achievement of this changed condition, the operation of the refrigeration unit is pending beyond a limit power stage. Cooling and / or freezer with at least one refrigeration unit and at least one internal or external control and / or regulating unit, wherein the control and / or regulating unit and the refrigerating unit are connected to each other such that the refrigerating unit by the control and / or regulating unit is controllable, and wherein the refrigeration unit is selectively operable on one of at least two different power levels,
characterized,
in that a control algorithm is stored on the control and / or regulating unit, which specifies a method according to one of claims 1 to 12 for the operation of the refrigeration unit. Cooling and / or freezing appliance according to claim 13, characterized in that the control and / or regulating unit has a data interface via a characteristic of the energy can be obtained from a server or other data source and / or via which the control and / or regulating unit is connected to a server or other data source of an intelligent power network. The refrigerator and / or freezer according to claim 13 or 14, characterized in that the refrigeration unit has a operable at different speeds compressor and different power levels are preferably defined by different compressor speeds.

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