RU2517224C2 - Refrigerating device and method of refrigerating device cooling - Google Patents

Abstract

FIELD: heating.

SUBSTANCE: refrigerating device, in particular, a domestic refrigerating device, and the method of cooling of the refrigerating compartment of the refrigerating device, in particular, a domestic refrigerating device, according to which a compressor included into the refrigerating circuit of the refrigerating device, which is designed to cool the refrigerating compartment, alternately, depending on time, switches on and off, until temperature (T) of the refrigerating compartment is within the temperature range (ΔT),oriented to the specified temperature of the refrigerating compartment and limited by the upper temperature limit (T_O) and the lower temperature limit (T_U).

EFFECT: using this group of inventions makes it possible to realise cooling under lower costs for programming.

15 cl, 8 dwg

Description

Technical field

The invention relates to a refrigerating apparatus, in particular to a domestic refrigerating apparatus, and to a method for cooling a refrigerating apparatus, in particular a domestic refrigerating apparatus.

State of the art

In ordinary household appliances, the temperature can be controlled by relatively inexpensive electromechanical thermostats, which, however, make it possible to regulate the temperature in the internal cavity of a household refrigerator only with limited accuracy. An electromechanical thermostat can also provide regular thawing of the evaporator in the refrigeration circuit of a domestic refrigeration unit.

Conventional domestic refrigeration appliances can also use more expensive electronic temperature control / adjustment devices, which allow you to set the desired temperature in a domestic refrigeration appliance with relative accuracy. As a rule, a temperature sensor is installed in the internal cavity of such household refrigerating appliances.

Disclosure of invention

The objective of the invention is to develop a more economical method of cooling a domestic refrigeration apparatus.

According to the invention, this problem is solved by a method of cooling the refrigerating compartment of a refrigerating apparatus, in particular a domestic refrigerating apparatus, the method involving alternately turning the compressor off and on (depending on time, in particular using a control device of the refrigerating apparatus) included in the refrigerating circuit of the refrigerating apparatus intended for cooling the refrigerator compartment, and the compressor is alternately turned off and on until the temperature is cold of the separate compartment fits into the temperature range oriented to the set temperature of the refrigerator compartment and limited by the upper temperature limit and the lower temperature limit.

In addition, the invention relates to a refrigerating apparatus, in particular a domestic refrigerating apparatus, which comprises a housing, a thermally insulated refrigerating compartment located inside the housing, a refrigerating circuit for cooling the refrigerating compartment comprising a compressor, and a control device that activates the compressor so that the temperature refrigeration compartment, at least approximately corresponded to the set temperature of the refrigeration compartment, that is, turns on and off the compressor for cooling REPRESENTATIONS refrigerating compartment in accordance with the method according to the invention.

Under the domestic refrigerator in the context of this invention refers to a refrigerator intended for domestic purposes, such as a refrigerator, freezer, chest freezer or combined refrigeration and freezer.

According to the method described by the invention, the refrigeration circuit for cooling the refrigeration compartment to its predetermined temperature is controlled not by purely controlling the temperature at which the controlled temperature is essentially the temperature of the refrigeration compartment, but by alternately turning the refrigeration circuit on and off, that is, its compressor. Due to this, the periods of operation of the compressor, that is, the periods of its inclusion, can consciously be made relatively short. In refrigerators, in particular in household refrigerators, relatively small temperature fluctuations can result in relatively low energy consumption. An evaporation temperature close to a predetermined temperature with relatively small fluctuations can also help reduce the energy consumption of the task. A deliberately short turn-on time results in relatively low power consumption.

Alternately (depending on time) turning off and on the compressor correspond to the phases of turning on and / or turning off the compressor. Such phases of turning on and / or turning off the compressor can have an equal duration. In particular, the duration of the on phase can be equal to the duration of the off phase. It is also possible that the duration of the on-phase will be longer or shorter than the duration of the compressor off phase. In addition, a variant is also possible in which a time sequence of compressor turn-on phases of different durations and / or compressor turn-off phases of different durations will be set. In this case, the compressor is switched off and on alternately (depending on time) in accordance with such a given time sequence. The duration of the on and / or off phases or their time sequence is stored in the control device, in particular in the memory of the control device. In addition, in the control device, in particular in the memory of the control device, the upper and lower temperature limits associated with a given temperature are stored.

In one embodiment of the method described by the invention, alternately (depending on time) turning the compressor off and on starts when the temperature in the refrigerator compartment drops below the upper temperature limit. If the temperature in the refrigerator compartment is above the upper temperature limit, then the compressor can operate continuously until, as this variant of the method according to the invention provides, the temperature in the refrigerator compartment drops below the upper temperature limit. At this moment, the compressor switches off and on depending on the time, as a result of which the average operating time of the compressor is reduced, and the temperature in the refrigerator compartment, at least for a certain time, fluctuates within a given temperature range.

It is also possible that the compressor turns off and on alternately (depending on time) when the temperature in the refrigerator compartment drops below the lower temperature limit. According to this option, when, for example, the temperature in the refrigerator compartment is too high, and the compressor runs continuously and thereby continuously cools the refrigerator compartment, the cooling power can be reduced by controlling the compressor turning on and off depending on the time, in order to prevent further cooling the refrigerator compartment. However, unlike the conventional cooling method, the compressor does not turn off until the upper temperature limit is reached, but turns off and on alternately depending on the time.

Preferably, alternately (depending on the time) turning off and on of the compressor starts from the off phase. In particular, in the variant that provides for alternating (depending on the time) switching off and on of the compressor when the temperature drops below the lower temperature limit, this is advantageous in that when the lower temperature limit is reached, the compressor is immediately turned off and that the temperature in the refrigerator compartment drops slightly further .

According to the next variant of the method described by the invention, during alternate (time-dependent) shutdown and shutdown, the compressor is turned off and, therefore, remains turned off only when the temperature in the refrigerator compartment drops below the upper temperature limit at the time of a potential shutdown. Thereby, it can be guaranteed that the current temperature in the refrigerator compartment will not be too high compared to the set temperature.

In the next embodiment, alternating (depending on the time) switching off and on of the compressor can begin only when the temperature in the refrigerator compartment drops below the lower temperature limit. Thereby, it can be ensured that the temperature in the refrigerator compartment does not drop too low, and that the temperature in the refrigerator compartment fluctuates substantially within a temperature range limited by two temperature limits.

It is also possible that the compressor is first turned off when the temperature in the refrigerator compartment drops below the lower temperature limit, and the alternate (depending on the time) shutdown and start of the compressor resumes only when the temperature in the refrigerator compartment exceeds the upper temperature limit.

In order to prevent an excessive decrease in temperature in the refrigerator compartment during the time-controlled compressor turning on and off, in the next embodiment of the method described by the invention, the compressor is turned off during the time-controlled switching off and on as soon as the temperature in the refrigerator compartment drops below the lower temperature limit. In one embodiment of the method described by the invention, alternating (depending on the time) turning off and on of the compressor can only be resumed when the temperature in the refrigerator compartment exceeds the lower temperature limit. Alternatively, alternating (depending on the time) switching off and on of the compressor can be resumed only when the temperature in the refrigerator compartment exceeds the upper temperature limit.

In order to prevent icing of the evaporator of the refrigeration circuit, in one embodiment of the method described by the invention, the compressor may be switched off at the beginning of the defrost phase of the evaporator.

The defrost phase can begin, for example, when the temperature of the evaporator drops below the set limit temperature.

The method according to the invention or the refrigerating apparatus according to the invention, depending on the embodiment, ensures that the desired (predetermined) temperature is maintained in the refrigerator compartment with relatively small temperature fluctuations and, thereby, reduced energy consumption. In addition, if necessary, due to the controlled thawing of the evaporator, the operation of the function can be ensured during operation of the refrigeration apparatus according to the invention.

Depending on the embodiment, it is possible to use an electronic control / adjustment device, which, if necessary, implements a free choice of switching values (first and second temperature limits), defrosting processes and setting the exact temperature in the refrigerator compartment. If necessary, a sensor installed on the evaporator, such as a capillary thermostat sensor, transmits the temperature value on the evaporator to ensure complete defrosting of the evaporator. Depending on the embodiment, by setting the appropriate tolerance field limited by the corresponding on and off values, i.e. the lower and upper temperature limits, it can be guaranteed that the temperature in the refrigerator compartment does not drop excessively low or does not rise excessively high. In one embodiment, the refrigeration machine (refrigeration circuit or its compressor) operates continuously while the temperature in the refrigerator compartment is above the upper temperature limit. Inside the tolerance field, the operating time of the chiller is tightly defined. Maintaining the set (set) temperature is guaranteed due to periods of downtime of the chiller. If this is not enough to maintain the temperature in the refrigerator compartment within the tolerance range, for example, due to the relatively high ambient temperature, the frequent use of the refrigerator according to the invention or the laying of warm products, the chiller can turn on and work again until the desired temperature is reached again.

If such cycles do not provide complete defrosting of the evaporator, then the electronics (control device) can periodically start the defrost phase, during which the evaporator is completely defrosted.

The method described by the invention, which saves energy, can be implemented with relatively low programming costs and, essentially, without increasing the cost of hardware. At the same time, user functions do not degrade.

Brief Description of the Drawings

Embodiments of the invention are described on the basis of the attached schematic figures, which depict:

Figure 1: household refrigeration unit;

Figures 2-8: diagrams illustrating a method of cooling a domestic refrigerator.

The implementation of the invention

The figure 1 shows a household refrigeration unit 1 with a housing 2 and a door 3, hung on the housing 2, for example, using hinges not shown in the figure. The door 3 in the closed state closes the refrigerator compartment 4, limited by the housing 2, and in the open state opens access to it, so that it is possible to put refrigerated products in the refrigerator compartment 4 or to remove them from it. Domestic refrigeration apparatus 1 may include shelves and / or door hinges that are designed to store refrigerated products and are not shown in the figure, although they are essentially known to specialists.

In addition, the household refrigeration apparatus 1 comprises a refrigeration circuit 5 known to the person skilled in the art, which is designed to cool the refrigeration compartment 4 in accordance with a predetermined set temperature. The refrigeration circuit 5 includes, inter alia, a compressor 6 and an evaporator 7, which are essentially known in the art.

In the proposed embodiment, the temperature T in the refrigerator compartment 4 is controlled using an electronic control device 8, which, for example, contains a microcontroller or microprocessor and is connected to the compressor 6 (the connection is not shown in the figure) in order to turn it on and off to control the temperature T or its adjustments. Figure 2 illustrates the process of controlling / adjusting the temperature T in the refrigeration compartment 4. To determine the actual temperature (temperature T in the refrigeration compartment 4), the household refrigeration apparatus 1 comprises a temperature sensor 9 that is installed in the refrigeration compartment and connected to the control device 8 (connection not shown on the figure).

In addition, the household refrigeration apparatus 1 contains another temperature sensor 10, which is connected to the control device 8 (the connection is not shown in the figure), determines the temperature of the evaporator 7 and transmits the corresponding signal to the control device 8.

In the proposed embodiment, the control device 8 is arranged in such a way that it can control the temperature T in the refrigeration compartment 4 by turning the compressor 6 on and off or regulate this temperature, and Figure 2 shows an example of a graph of 11 phases Δt _ein on and off Δt _aus , as well as characteristic 12 of temperature T in the refrigerator compartment 4.

Regulation (control) of temperature T in the refrigerator compartment 4 in the proposed embodiment is as follows.

When setting a predetermined temperature for the refrigerator compartment 4, a predetermined temperature tolerance field ΔT is formed, which is limited by the upper temperature limit T _O and the lower temperature limit T _U.

If the household refrigeration unit 1 was turned on, for example, at time t ₀ , and the actual temperature T in the refrigeration compartment 4 exceeds the upper temperature limit T _O , then the electronic control device 8 turns on the compressor 6, as a result of which the refrigeration circuit 5 cools the refrigeration compartment 4, and the temperature T in the refrigerator compartment 4 drops.

If the temperature T in the refrigerator compartment 4 at the time t ₁ reaches the lower temperature limit T _U or falls below this limit, then the control device 8 turns off the compressor 6. Given the relatively inert reaction of the temperature T, the temperature T in the refrigerator compartment 4 continues to drop for a short time after turning off the compressor 6 at time t ₁ , after which it begins to rise until it reaches the upper temperature limit T _O at time t ₂ or exceeds it.

When reaching or exceeding the upper temperature limit T _O at time t _{2, the} control device 8 again turns on the compressor 6. Given the relatively inert reaction of temperature T, the temperature T in the refrigerator compartment 4 continues to rise for a short time after turning on the compressor 6, after which it starts to drop again .

Further, in accordance with the schedule, the control device 8 alternately turns off the compressor 6 at times t ₃ , t ₅ , t ₇ , etc. and turns it on at times t ₄ , t ₆ , etc. Thus, there are time-controlled control device 8, replacing each other on phase Δt _ein on and phase Δt _aus off compressor 6.

In the proposed embodiment, the turn-on phases Δt _ein and turn-off phases Δt _{aus of the} compressor 6 are of equal duration. This feature is optional. It is also possible that the switching phases Δt _{ein are} longer or shorter than the compressor shutdown phases AΔt _aus 6. In addition, you can set the sequence of phases Δt _{ein of} turning on the compressor 6 of various durations and / or phases Δt _{aus of} turning off the compressor 6 of various durations.

The on-phase Δt _ein and on-off phase Δt _{aus of the} compressor 6 depend on time, and not on temperature. In order to approximately maintain the temperature set for it in the refrigerator compartment 4, in the proposed embodiment, it is provided that if the temperature T of the refrigerator compartment 4 or the temperature T of the refrigerator compartment 4, determined by the temperature sensor 9, at a time-dependent moment t ₃ , t ₅ , t ₇ etc. switching off exceeds the upper temperature limit T _O , then the control device 8 does not turn off the compressor 6, that is, keeps it on until the temperature T in the refrigerator compartment 4 reaches the lower temperature limit T _U or falls below it. After the temperature T of the refrigerator compartment 4 drops below the lower temperature limit T _U , the control device 8 turns off the compressor 6 again and starts turning the compressor 6 on and off depending on the time until the temperature T in the refrigerator compartment 4 reaches the upper temperature limit T again _O or not to exceed it.

If, in the proposed embodiment, the temperature T of the refrigerating compartment 4 during the on and off of the compressor 6, depending on the time, falls below the lower temperature limit T _U , then the control device 8 will turn off the running compressor 6 and start turning the compressor 6 on and off, depending on the time the temperature T in the refrigerator compartment 4 again does not reach the upper temperature limit T _O or does not exceed it.

To ensure, if necessary, the thawing of the evaporator 7, in the proposed embodiment, the control device 8 monitors the temperature of the evaporator 7 using a temperature sensor 10. If the measured temperature of the evaporator 7 reaches or falls below a predetermined temperature, then the control device 8 switches off, for example, the compressor 6 set minimum time or until the moment at which the temperature of the evaporator 7 reaches the next set temperature or exceeds it. After that, the control device 8 again turns on the compressor 6 and does not turn it off until the temperature T in the refrigerator compartment 4 reaches the lower temperature limit T _U or falls below it. Then, the control device 8 starts turning the compressor 6 on and off, depending on the time, until the temperature T in the refrigerator compartment 4 again reaches the upper temperature limit T _O or exceeds it.

In figures 3-5 presents an alternative method of cooling the refrigerator compartment 4, in accordance with which the control device 8 alternately turns off and turns on the compressor 6 depending on the time when the temperature T in the refrigerator compartment 4 at time t ₁ falls below the lower temperature limit T _U.

In the proposed embodiment, an alternating, time-dependent shutdown and start-up of the compressor 6 starts from the shutdown phase Δt _aus , which lasts from time t ₁ to time t ₂ . At time t _{2, the} control device 8 turns on compressor 6, and the start phase Δt _ein starts, which lasts until time t ₃ . As long as the temperature T of the refrigerator compartment 4 remains within the temperature range ΔT, the control device 8 activates the compressor 6 depending on the time so that it turns on and off alternately.

During the alternate (depending on the time) switching off and on of the compressor 6, it may happen that the average operating time of the compressor is reduced so that the temperature T of the refrigeration compartment 4 exceeds the upper temperature limit T _O , as occurs at time t ₈ (see figure 4). In the proposed embodiment, the control device 8 turns on the compressor 6 even during the shutdown phase Δt _aus , if it detects that the upper temperature limit T _{O is} exceeded. Due to this, the temperature T in the refrigerator compartment 4 decreases.

In the proposed embodiment, the compressor 6 remains on until the temperature T in the refrigerator compartment 4 falls below the lower temperature limit T _U , which in the embodiment shown in figure 4 takes place at time t ₉ . At time t _{9, the} control device 8 again turns off the compressor and starts to turn on and off the compressor 6 depending on the time while the temperature T in the refrigerator compartment 4 is within the temperature range ΔT.

If the temperature T in the refrigerator compartment 4 falls below the lower temperature limit T _U during the alternate (depending on time) on and off compressor 6, as is the case at time t ₇ (see figure 5), then, in the proposed embodiment execution, the control device 8 turns off the compressor 6, even if the phase Δt _{ein of} turning it on, and the phase Δt _{aus of} turning off in the alternating (depending on time) on and off of the compressor 6 is already starting at time t ₈ .

Figures 6-8 show an alternative cooling option for the refrigerator compartment 4, according to which the control device 8 alternately turns off and turns on the compressor 6 depending on the time when the temperature T in the refrigerator compartment 4 at time t ₁ falls below the upper temperature limit T _O.

In the proposed embodiment, an alternating, time-dependent shutdown and start-up of the compressor 6 starts from the shutdown phase Δt _aus , which lasts from time t ₁ to time t ₂ . At time t _{2, the} control device 8 turns on compressor 6, and the start phase Δt _ein starts, which lasts until time t ₃ . As long as the temperature T of the refrigerator compartment 4 remains within the temperature range ΔT, the control device 8 activates the compressor 6 depending on the time so that it turns on and off alternately.

During the alternate (depending on the time) switching off and on of the compressor 6, it may happen that the average operating time of the compressor is reduced so that the temperature T of the refrigerator compartment 4 exceeds the upper temperature limit T _O , as occurs at time t ₆ (see Fig.7). In the proposed embodiment, the control device 8 includes a compressor 6, if it detects an excess of the upper temperature limit T _O. Due to this, the temperature T in the refrigerator compartment 4 decreases.

In the proposed embodiment, the compressor 6 remains on until the temperature T in the refrigerator compartment 4 drops below the lower temperature limit T _U , which in the embodiment shown in figure 7 takes place at time t ₇ . At time t _{7, the} control device 8 again turns off the compressor and starts alternately turning the compressor 6 on and off depending on the time while the temperature T in the refrigerator compartment 4 is within the temperature range ΔT.

If the temperature T in the refrigerator compartment 4 falls below the lower temperature limit T _U during the alternate (depending on time) on and off compressor 6, as is the case at time t ₇ (see Fig. 8), then, in the proposed embodiment execution, the control device 8 turns off the compressor 6, even if the phase Δt _{ein of} its inclusion is still ongoing. In the proposed embodiment, the alternate (depending on time) switching on and off of the compressor 6 begins only at time t ₈ , at which the temperature T in the refrigerator compartment 4 exceeds the upper temperature limit T _O. However, in this embodiment, the alternate (depending on the time) switching on and off of the compressor 6 starts at time t ₈ with the switching phase Δt _ein .

Claims (15)

1. The method of cooling the refrigeration compartment (4) of the refrigeration apparatus, in particular the household refrigeration apparatus (1), characterized in that it involves alternately turning the compressor off and on (6) depending on time, in particular using a control device (8) of the refrigeration apparatus (1), moreover, the compressor (6) enters the refrigeration circuit (5) of the refrigeration apparatus, designed to cool the refrigeration compartment (4), and the compressor (6) is turned off and on alternately until the temperature (T) of the refrigeration unit compartment (4) fits into the temperature range (ΔТ), oriented to a given temperature of the refrigeration compartment (4) and limited by the upper temperature limit (T _O ) and the lower temperature limit (T _U ). 2. The method according to claim 1, characterized in that the phases (Δt _ein ) on and / or phases (Δt _aus ) off the compressor (6), corresponding to alternately, depending on the time, turn off and on the compressor (6), have equal the duration and / or phases (Δt _ein ) of switching on last as long as the phases (Δt _aus ) of turning off the compressor (6), and / or the duration of phases (Δt _ein ) of turning on more or less than the duration of phases (Δt _aus ) of turning off the compressor ( 6). 3. The method according to claim 1, characterized in that the time sequence of phases (Δt _ein ) of turning on the compressor of various durations and / or phases (Δt _aus ) of turning off the compressor (6) of various durations and that the compressor is turned off and on alternately depending on the time is set (6) is produced in accordance with such a predetermined time sequence. 4. The method according to claim 1, characterized in that alternately, depending on the time, turning the compressor off and on (6) starts when the temperature (T) in the refrigerator compartment (4) falls below the upper temperature limit (T _O ). 5. The method according to claim 1, characterized in that the alternate, depending on the time, turning the compressor off and on (6) starts when the temperature (T) in the refrigerator compartment (4) falls below the lower temperature limit (T _U ). 6. The method according to claim 1, characterized in that the alternate, depending on the time, turning the compressor off and on (6) starts from the shutdown phase (Δt _aus ). 7. The method according to claim 1, characterized in that during the alternate, depending on the time, off and on, the compressor (6) is turned off and thereby remains off only when the temperature (T) in the refrigerator compartment (4) at the time potential shutdown below the upper temperature limit (T _O ). 8. The method according to claim 7, characterized in that alternately, depending on the time, turning off and on the compressor (6) only starts when the temperature (T) in the refrigerator compartment (4) drops below the lower temperature limit (T _U ) . 9. The method according to claim 7, characterized in that the compressor (6) is turned off when the temperature (T) in the refrigerator compartment (4) falls below the lower temperature limit (T _U ), and alternately, depending on the time, turning it off and on compressor (6) resume only when the temperature (T) in the refrigerator compartment (4) exceeds the upper temperature limit (T _U ). 10. The method according to claim 1, characterized in that the compressor (6) is turned off during alternate, depending on the time, turning the compressor off (6) and turning it on immediately as soon as the temperature (T) in the refrigerator compartment (4) drops below lower temperature limit (T _U ). 11. The method according to claim 10, characterized in that alternating, depending on the time, turning the compressor off and on (6) is resumed only when the temperature (T) in the refrigerator compartment (4) exceeds the lower temperature limit (T _U ). 12. The method according to claim 10, characterized in that alternating, depending on the time, turning the compressor off and on (6) is resumed only when the temperature (T) in the refrigerator compartment (4) exceeds the upper temperature limit (T _O ). 13. The method according to claim 1, characterized in that the compressor (6) is turned off at the beginning of the thaw phase of the evaporator (7). 14. The method according to item 13, wherein the defrost phase begins when the temperature of the evaporator (7) falls below a predetermined limit temperature. 15. The refrigerating apparatus, in particular the household refrigerating apparatus, which comprises a housing (2), a thermally insulated refrigerating compartment (4) located inside the housing (2), a refrigerating circuit (5) for cooling the refrigerating compartment (4), comprising a compressor (6) and a control device (8) that activates the compressor (6) so that the temperature (T) in the refrigerator compartment (4) at least approximately matches the set temperature of the refrigerator compartment (4), characterized in that the control device ( 8) turns on and off yuchaet compressor (6) for cooling the refrigerating compartment (4) in accordance with the method according to one of claims 1-14.

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