EP2522942A1 - Refrigeration and/or freezer device - Google Patents

Abstract

The device has a fan arranged in a refrigerated inner space or in a space that is connected with the refrigerated inner space. A temperature sensor is arranged such that the temperature sensor is provided at a certain location of the device. A control or regulation unit is connected with the temperature sensor and a fan and formed such that the control or regulation unit reduces rotation speed of the fan if time span is shorter than predetermined time span-threshold value. A refrigerant circuit is provided with a compressor for compressing refrigerant. An independent claim is also included for a method for operating a refrigeration and/or freezer device.

Description

The present invention relates to a refrigerator and / or freezer with at least one refrigerated interior space and with at least one fan, which is arranged in the cooled interior or in a communicating with the cooled interior space, and with at least one temperature sensor, which is arranged in that it measures the temperature, preferably the air temperature, at least at one point of the appliance, preferably in the cooled interior or in the space communicating therewith.

From the prior art refrigerators and / or freezers with a so-called dynamic cooling are known. In these devices, the air distribution in the cooled interior is made partially or completely by means of at least one fan, which may be arranged for example in or in the region of a cooling air duct of the device. Devices known from the prior art have, for example, a cooling air duct in the rear region of the device, which has an upper inlet opening and a lower outlet opening, wherein the upper inlet opening is in the region of a cooling compartment and the lower outlet opening is arranged in the range of a cold storage compartment. The flow through this cooling air duct, in which at least at least one evaporator is arranged, takes place partially or completely by means of a fan, which conveys the air into the cooling air duct and in total ensures an air circulation in the compartments to be cooled.

The present invention relates, inter alia, also to such devices, but is not limited to these devices and in particular also not to the arrangement of said compartments.

In known devices, said fan is operated at two different speeds, wherein a first speed is selected when the compressor of the refrigerant circuit of the refrigerator and / or freezer and a second speed when not in operation, that is, when the compressor is stopped.

The fan speed is therefore independent of the cooling power requirement and only dependent on the operation of the compressor.

The speeds mentioned are chosen in known from the prior art devices so that there is always a sufficient air or cooling capacity, especially at higher ambient temperatures and comparatively low setpoints for the temperature or corresponding regulator positions available.

Although this procedure leads to a sufficient cooling capacity of the device, but is associated with the disadvantage that even at normal room temperatures due to the fan operation noise and that there is a higher energy consumption.

The present invention is therefore the object of developing a refrigerator and / or freezer of the type mentioned in such a way that this more energy-efficient and quieter than known from the prior art devices.

This object is achieved by a refrigerator and / or freezer with the features of claim 1. Thereafter, the device has at least one control or regulating unit, which communicates with the at least one temperature sensor and with the at least one fan and which is designed such that it reduces the speed of the fan when the period in which the cooling power requirement exists is shorter than a predetermined first time period limit.

Thus, it is determined that the period of time in which a cooling power requirement exists, i. E. the time between reaching the switch-on and reaching the switch-off exceeds a certain limit, the speed of the fan is reduced. This can be done during an operating cycle of the compressor or the fan or the next time you turn on the compressor or the fan.

In a further embodiment of the invention, it is provided that the control or regulating unit is designed such that it increases the speed of the fan when the time period in which the cooling power requirement is greater than a predetermined second time period limit.

The first and second timeout limits may be identical or different.

In a further embodiment of the invention it is provided that a speed increase of the fan additionally requires that the temperature measured by the temperature sensor at the first limit plus a Δ value, that is plus a surcharge or more than this sum. The predetermined by the control or regulating unit control or regulating algorithm thus provides in a preferred embodiment that made a speed increase when the chiller request lasts longer than x minutes and the chilled air sensor or other temperature sensor detects a higher temperature than the fan on, ie as the upper temperature limit plus a Δ value.

According to the invention, it is provided that a speed reduction occurs when the cooling part requirements take less than xy minutes.

The said time periods "x" and "xy" as well as the Δ value can be fixed or also variable, for example at the factory or the user can be adjustable.

In a preferred embodiment of the invention is thus an adaptive fan control, with which it is possible to approach the lowest possible fan speed. As a result, fan noise in most cases will not be perceived as disturbing under normal environmental conditions.

Another advantage is that the comparatively low fan speed, the duty cycle of the fan is high, which leads to small temperature fluctuations in the device and to a safe defrosting of the evaporator. This in turn has the advantage of low compressor life and low power consumption.

However, if higher ambient temperatures are present and / or there is a low temperature setpoint due to a correspondingly "cold" controller position, the algorithm of the control at higher fan speeds also allows this requirement for cooling capacity to be covered.

In a further embodiment of the invention it is provided that the increase and / or the reduction of the rotational speed of the fan takes place stepwise and / or continuously and / or that in the case of a stepwise change in the rotational speed the fan is an increase and / or a reduction in the speed in the form of exactly one stage or in the form of multiple stages.

If, for example, it is determined that the cooling part requirement lasts longer than x minutes or another period of time and is measured by the temperature sensor, which is preferably designed as Kühlteilluftfühler, a temperature which is higher than the Ventilatoreinschaltwert, that is, as the first limit, plus one Δ value, it can be provided that a continuous or a gradual increase in the speed of the fan takes place. If after a further period of time, for example xx minutes, the temperature measured by the temperature sensor is still higher than the fan switch-on value plus the Δ value or corresponds to this sum, it can be provided that a further increase in the speed of the fan either stepwise or continuously.

Furthermore, it is conceivable that a speed reduction takes place if the cooling part requirement lasts shorter than xy minutes. In this way it is possible to choose the fan speed as low as possible. If the requirement of the cooling capacity is below a limit value, for example, in the next operating phase of the fan, it is operated at a lower speed than in the preceding operating phase. In this way, a repeated reduction of the fan speed is possible.

If there is a cooling capacity requirement in an operating interval of the fan for less than a predetermined period of time, it is intended to operate the fan in the following operating interval of the fan at a lower speed than in the previous interval. This can be continued accordingly for the following intervals. If, however, it is determined within an operating interval that the cooling power requirement is above the upper temperature limit value, ie above the switch-on value of the fan or compressor, at least for a predetermined period of time, and additionally at a value which corresponds at least to the fan switch-on value plus a Δ value it is conceivable while This operating interval of the fan - as stated above - or in the next phase of operation to increase the speed of the fan gradually or continuously.

In a further embodiment of the invention it is provided that the control or regulating unit is designed such that it turns on the fan or leaves on when the temperature measured by the temperature sensor rises above the upper temperature limit or reaches the upper temperature limit.

If, for example, the temperature has fallen below the lower temperature limit and then rises again to or above the upper temperature limit, in this case, the fan is turned on again.

It is also conceivable that the fan remains switched on when the temperature has not fallen below the lower temperature limit, but is, for example, between the first and the second temperature limit and then again reaches or exceeds the upper temperature limit.

In a further embodiment of the invention it is provided that the control or regulating unit is designed such that it switches off the fan when the temperature measured by the temperature sensor falls below or to a lower temperature limit, the lower temperature limit below the upper Temperature limit is and is preferably provided that the control or regulating unit is designed such that it keeps the fan off until the temperature determined by the temperature sensor reaches or exceeds the upper temperature limit.

In a further embodiment of the invention, the device comprises at least one refrigerant circuit with at least one compressor for compressing the refrigerant, wherein the compressor is designed or controlled so that operating times are provided, in which the compressor is in operation, and that Stand times are provided, in which the compressor is not in operation, wherein the control or regulating unit is designed such that the fan is operated at befindlichem compressor in operation at a higher speed than befindlichem not in operation compressor. In addition to the adaptive fan control described above, which constitutes an advantageous embodiment of the present invention, it is thus conceivable to reduce the fan speed during the compressor service life.

Preferably, it is provided that the fan is switched on in the period in which cooling power requirement exists and is switched off in the period in which no cooling power requirement exists.

The present invention further relates to a method of operating a refrigerator and / or freezer according to any one of claims 1 to 9, wherein the speed of the fan is reduced if the time period in which cooling power demand is shorter than a predetermined first time periods -Limit.

It is preferably provided that the rotational speed of the fan is increased when the time period in which the cooling power requirement exists is greater than a predetermined second time span limit value.

It is conceivable that the speed of the fan is increased when the period in which the cooling power requirement exists, is greater than a predetermined second time period limit and when the measured temperature is greater than the upper temperature limit, if necessary plus a delta value ,

The increase and / or the reduction of the speed of the fan can be done gradually and / or continuously. In the case of a stepwise change in the speed of the fan, an increase and / or reduction of the speed can take place in the form of exactly one or more stages.

Figur 1:

eine schematische Darstellung des Temperaturverlaufs über die Zeit sowie des Verlaufs der Betriebsspannung des Ventilators über die Zeit in einem ersten Ausführungsbeispiel und

Figur 2:

eine schematische Darstellung des Temperaturverlaufs über die Zeit sowie des Verlaufs der Betriebsspannung des Ventilators über die Zeit in einem zweiten Ausführungsbeispiel mit zusätzlicher Darstellung der Kompressorlauf- und -standzeit.

Further details and advantages of the invention will be described with reference to an embodiment shown in the drawing. Show it:

FIG. 1:

a schematic representation of the temperature profile over time and the course of the operating voltage of the fan over time in a first embodiment and

FIG. 2:

a schematic representation of the temperature profile over time and the course of the operating voltage of the fan over time in a second embodiment with additional representation of the compressor run and service life.

In FIG. 1 at the top of the ordinate, the temperature is measured, which is measured by an air sensor located in the cooled interior of a refrigerator and / or freezer.

The abscissa shows the time.

Like this FIG. 1 As a result, there exists a turn-on value (EW) and a turn-off value (AW) which are the upper temperature limit value and the lower temperature limit value according to the present invention.

FIG. 1 below, the ordinate shows the fan voltage, which is proportional to the fan speed, and the abscissa the time.

Like this FIG. 1 shows that at time T _0, the temperature measured by the temperature sensor is above the switch-on value. In this case, the fan is operated at a certain speed, in the present example with a voltage of 8V. At a time T ₁ , it is determined that the measured temperature is already above the switch-on value for a certain duration and, in addition, the value of the switch-on temperature plus a Δ value or exceeds, so that at this time T, the fan voltage is increased by 0.5V and thus an increase in the speed is made.

At time T ₂ , the temperature measured by the temperature sensor reaches the switch-off value AW, that is to say the second limit value, with the result that the fan is switched off.

In the next operating interval of the fan, an exceeding of the switch-on value is detected by the measured temperature at time T ₃ , with the result that the fan is put back into operation. The operating voltage of the fan corresponds to the operating voltage at the beginning of the previous interval, namely 8V.

Like this further FIG. 1 shows, at the time T _4, the switch-off, that is, the second threshold falls below, which causes the fan at time T _{4 is} turned off again.

In the next and third illustrated operating interval of the fan is again switched on reaching the switch-on at the time T _5, the fan, but the operating voltage of the fan is less than that of the previous interval. This is due to the fact that in the previous operating interval, that is to say in the second operating interval, the time period T ₃ to T _{4 is} shorter than a specific limit value. In the embodiment shown here, the fan is thus operated in the third operating interval with a voltage of 7.5V.

At time T ₆ , the fan is switched off, since the measured, falling temperature reaches or falls below the switch-off.

Since in the third operating interval of the fan, the duration of the cooling part request, that is, the time period T ₅ to T _{6 is} less than a limit, is in the fourth Operating interval between the times T ₇ and T _{8 made} a further reduction of the operating voltage of the fan, resulting in a further reduction in the speed of the fan. As stated above, the low fan speed leads to an increased duty cycle of the fan, but to lower temperature fluctuations in the unit and to a safe defrosting of the evaporator. This in turn leads to low compressor life and low power consumption.

The operating and off phases of the fan are the same as those of the compressor, i. On and off values refer to both the fan and the compressor.

FIG. 2 shows a further embodiment of the operation of the refrigerator and / or freezer according to the invention, wherein in FIG. 2 above again on the ordinate the temperature of the air sensor and on the abscissa the time is plotted. Underneath is the voltage of the fan on the ordinate and the time on the abscissa. Additionally is in FIG. 2 below with the reference numeral A represents the compressor power.

In the in FIG. 2 illustrated embodiment, the switch-on of the temperature is reached or exceeded at time T ₁ , which means that the fan is set in the embodiment shown here with a voltage of 6.5V in operation. At time T ₂ , the compressor is turned off, which causes the fan is automatically reset to a lower speed, that is, operated at a lower voltage, which is 6V in the embodiment shown here. If the compressor is switched on again, which is the case at time T ₃ , the fan is operated again with the same operating voltage, that is to say at 6.5 V, as in the first preceding operating interval.

At time T ₄ , a warm load is introduced into the refrigerator and / or freezer, resulting in an in FIG. 2 above temperature increase leads. To the Time T ₅ , the compressor switches off again, which as described leads to a specific reduction of the fan voltage and speed.

At time T ₆ , the temperature measured by the air sensor reaches the first limit value, that is to say the switch-on value, due to the heat input. The fan is still operated at the lower speed or voltage and only raised again to the aforementioned value of 6.5 V when the compressor turns on again. This is the case at time T ₇ .

At the time T ₈ , it is determined that since the start of the run of the counter, that is from the time T _6, a certain period of time has elapsed, in which the temperature is above the switch-on value. In addition, it is determined that at this time (T ₈ ) the measured temperature is above the switch-on value plus a Δ value. This means that at this time the speed of the fan is increased by a certain amount, in the embodiment shown here by 0.5V to 7V, which is accompanied by a corresponding increase in the speed.

At the time T ₉ it is determined that since the start of the counter run, that is, since reaching the time T _6, a further time period has expired and the measured temperature value is still above the switch-on value plus a Δ value. This means that at the time T9, a further stepwise increase in the voltage of the fan to the value of 7.5V and thus also the fan speed.

Like this further FIG. 2 shows the performance of the compressor is continuously reduced during its intervals operating time. Out FIG. 2 also shows that the speed of the fan or the fan voltage in the service life of the compressor is below that, as it is set in the operating times of the compressor.

As stated above, a Regelalgoritmus may be configured such that an increase in speed is present when the cooling part requirement lasts longer than x minutes, that is, when the temperature is greater than x minutes above a switch-on and the Kühlteilluftfühler or another temperature sensor measures a higher temperature than the fan switch-on value plus a Δ value. This time span or Δ value can represent variable parameters. In FIG. 2 the time period "x" is formed by the intervals T ₆ -T ₈ and T ₆ -T ₉ .

As also shown, there may be a reduction in speed when the cooling part requirements is shorter than xy minutes, and this period may be variably adjustable.

Further parameters with which the device can be operated are the initial speed or initial voltage (for example 8V) of the fan, the minimum speed and the maximum speed of the fan, each with voltage values z. B. of 6V and 10V can be correlated, as well as the speed or voltage steps, which may be in both directions, that is both in the increase and in the reduction, for example, 0.5V.

Claims (13)

Refrigerated and / or freezer with at least one cooled interior and with at least one fan, which is arranged in the cooled interior or in a communicating with the cooled interior space, and at least one temperature sensor, which is arranged such that it at least a location of the device, preferably in the cooled interior or in the space associated therewith, measures the temperature, wherein a cooling power requirement is in a period of time commencing at the time the measured temperature reaches or exceeds an upper temperature limit and ending with the time at which the measured temperature reaches or falls below a lower temperature limit, characterized in that at least one control unit is provided which is in communication with the temperature sensor and with the fan and which is designed such that that they are the speed of Ven tilators decreases when the time span in which
the cooling power requirement is shorter than a predetermined first time period limit. The refrigerator and / or freezer according to claim 1, characterized in that the control or regulating unit is designed such that it makes the reduction of the speed of the fan during operation of the compressor and / or at the beginning of a subsequent operating phase of the compressor. The refrigerator and / or freezer according to claim 1 or 2, characterized in that the control or regulating unit is designed such that it increases the speed of the fan when the time period in which the cooling power requirement is greater than a predetermined second time periods -Limit. The refrigerator and / or freezer according to claim 1 or 2, characterized in that the control or regulating unit is designed such that it increases the speed of the fan when the time period in which the cooling power requirement is greater than a predetermined second time periods Limit, and if the measured temperature is greater than the upper temperature limit, plus a delta value if applicable. The refrigerator and / or freezer according to claim 4, characterized in that the control or regulating unit is designed such that it carries out the increase in the speed of the fan during operation of the compressor and / or at the beginning of a subsequent operating phase of the compressor. Cooling and / or freezing appliance according to one of the preceding claims, characterized in that the increase and / or the reduction of the speed of the fan takes place stepwise and / or continuously and / or that in the case of a stepwise change in the speed of the fan an increase and / or reduction of the speed takes place in the form of exactly one or more stages. The refrigerator and / or freezer according to one of the preceding claims, characterized in that the control or regulating unit is designed such that it turns on the fan or leaves on when the temperature measured by the temperature sensor rises above the upper temperature limit or the reached upper temperature limit. Refrigerating and / or freezing appliance according to one of the preceding claims, characterized in that the control or regulating unit is designed such that it switches off the fan when the temperature measured by the temperature sensor falls below or to the lower temperature limit, preferably it is provided that the control or regulating unit is designed such that it keeps the fan off until the temperature determined by the temperature sensor reaches or exceeds the upper temperature limit value. The refrigerator and / or freezer according to one of the preceding claims, characterized in that the device has at least one refrigerant circuit with at least one compressor for compressing the refrigerant and that the compressor is designed or driven so that operating times are provided, in which the compressor is in operation, and that stand times are provided, in which the compressor is not in operation, wherein the control unit is designed such that the fan is operated at befindlichem compressor at a higher speed than in befindlichem befindlichem compressor , A method of operating a refrigerator and / or freezer according to any one of claims 1 to 9, characterized in that the speed of the fan is reduced when the period in which cooling power requirement is shorter than a predetermined first time period limit. A method according to claim 10, characterized in that the speed of the fan is increased when the period in which the cooling power requirement is greater than a predetermined second time period limit value. A method according to claim 10, characterized in that the speed of the fan is increased when the period in which the cooling power requirement is greater than a predetermined second time period limit and when the measured temperature is greater than the upper temperature limit, if necessary plus a delta value. A method according to any one of claims 10 to 12, characterized in that the increase and / or the reduction of the speed of the fan takes place stepwise and / or continuously and / or that in the case of a stepwise change in the speed of the fan, an increase and / or reduction the speed is in the form of exactly one or more stages.

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