Patent Application
20220026128
The present invention relates to a method for initializing a defrosting procedure in a refrigeration appliance, in particular a household refrigeration appliance, as well as to a refrigeration appliance in which the method can be applied.
Since frost that has condensed on an evaporator impairs the transfer of heat from a storage chamber of a refrigeration appliance to the evaporator, in a conventional refrigeration appliance with a compressor that can only switch between a switched-on and switched-off state, the switched-on phases of the compressor become longer and longer as the layer of frost grows thicker. In such a refrigeration appliance, a common method, e.g. described in KR 20010037545, is to decide the need for a defrosting procedure, to monitor the cumulative runtime of the compressor and the number of door openings since the last defrosting, and to start a defrosting procedure when a predefined limit value is exceeded.
Modern refrigeration appliances use multiple compressors, the rotational speed of which can be set to a plurality of non-vanishing values, also referred to as variable speed compressors in the following. In these refrigeration appliances, the conventional approach described above is unsatisfactory, because as the rate of frost buildup on the evaporator depends upon the rotational speed, it is no longer possible to make an assessment on the basis of the cumulative compressor runtime. U.S. Pat. No. 6,047,554 proposes, in such a case, to ascertain a weighted cumulative runtime, in which operating times with different rotational speeds are included with different weighting. Here, however, a prerequisite for a confident assessment of the frost thickness is that the relationship between compressor rotational speed and rate of frost buildup is known and can be reproduced.
An object of the present invention is to specify a method for initializing a defrosting procedure, which is simple to apply, allows a reliable estimation of the frost thickness and is suitable for a refrigeration appliance with variable speed compressor.
The object is achieved by a method with the steps of
a) starting up the compressor with a rotational speed set to an initial value n0,
b) adapting the rotational speed nt of the compressor, in order to prevent the temperature of a storage chamber of the refrigeration appliance from drifting from a setpoint temperature,
c) monitoring a deviation between the adapted rotational speed nt and the initial value n0, and
d) deciding that a defrosting is necessary when the deviation exceeds a limit value.
The adapting of the rotational speed is typically a continuous procedure, in which the rotational speed in each case is switched between a value that lies slightly above an ideal value which corresponds to the refrigeration requirement of the device but cannot be exactly achieved, and a value that lies slightly above said value, whenever a limit temperature is reached.
Apart from brief interruptions due to the opening of a door of the storage chamber or the inserting of goods to be refrigerated, the temperature of which deviates from the temperature of the storage chamber, the rotational speed of the compressor should substantially depend upon the temperature difference between storage chamber and surrounding environment. A systematic deviation of the rotational speed can then be traced to a transfer of heat between storage chamber and frost impairing the compressor, meaning that when this deviation exceeds a limit value it can be inferred that the layer of frost is thick enough to necessitate a defrosting.
In the simplest case, the deviation can be the current difference between the adapted rotational speed nt and the initial value n0; it is preferred, however, if previously measured differences also have an influence on the instantaneous value of the deviation. As a result, the deviation can then also change if the difference between adapted rotational speed nt and the initial value n0 is constant, but different from zero.
The monitoring of the deviation should in particular comprise at least increasing the deviation, if the adapted rotational speed nt lies above the initial value n0, meaning that, if the compressor runs continuously with a rotational speed above the initial value, the limit value has to be exceeded sooner or later.
In order to be able to account for brief interruptions more effectively, it should also be possible to reduce the deviation again in times in which the adapted rotational speed nt lies below the initial value n0.
A preferred possibility for this is to ascertain the deviation as a time integral of the difference (nt−n0) between the adapted rotational speed nt and the initial value n0. This integral can be formed over the entire runtime of the compressor since the last defrosting procedure. It is also conceivable, however, to exclude certain time periods from the formation of the integral, e.g. those in which the deviation is negative or lies between zero and a small negative limit value. In this way, it can be ensured that the deviation then also has a tendency to increase over time and leads to the start of a defrosting procedure when the adapted rotational speed nt does not significantly deviate from the initial value n0.
The adapting of the rotational speed of the compressor in step b) expediently comprises a lowering of the rotational speed nt in the event of falling below a first limit temperature of the storage chamber, and raising the rotational speed nt in the event of exceeding a second limit temperature of the storage chamber. The raising and lowering can take place continuously or in the form of discrete steps.
The initial value n0 can be ascertained empirically in the course of the method in each case. In particular, in each starting phase of the operation after a defrosting procedure, a rotational speed can be ascertained that proves to be suitable for maintaining the setpoint temperature in the storage chamber of the refrigeration appliance, and the initial value n0 can be derived from said rotational speed.
In the simplest case, the deriving consists in the ascertained suitable rotational speed being adopted as the initial value n0 in an identical manner.
Assuming that the temperature of the surrounding environment, in which the refrigeration appliance is placed, does not significantly change in the course of a plurality of defrosting cycles, the initial value n0 may also be formed by an average value of the suitable rotational speed ascertained after the last defrosting procedure and the suitable rotational speeds ascertained after one or more earlier defrosting procedures.
Moreover, it is conceivable to reduce the ascertained suitable rotational speed by a predefined amount and to adopt the result as initial value n0, in order to in this way ensure that the deviation grows over time and thus a defrosting procedure is triggered with certainty, or—with the same result—to choose the limit value as a decreasing function of the compressor runtime since the last defrosting procedure.
Alternatively, the initial value n0 may be predefined as a function of the ambient temperature. In order to detect this, a refrigeration appliance, in which the method according to the invention is applied, should be equipped with an ambient temperature sensor.
In the simplest case, the ambient temperature measured at the end of a defrosting procedure is used as an argument of the function; the initial value n0 then remains unchanged until the next defrosting procedure.
One advantage of the alternative, however, is that the initial value n0 can also be a function of the instantaneous ambient temperature, i.e. variable between two defrosting procedures. It can thus be avoided that an increase in the compressor rotational speed nt, traced back to a rise in the ambient temperature, is misinterpreted as evidence of a pronounced frost buildup and leads to a premature defrosting.
In order to ensure that a defrosting procedure is also triggered sooner or later if the compressor rotational speed nt stays the same on average, it is furthermore possible to choose the limit value as a decreasing function of the compressor runtime since the last defrosting procedure.
A further subject matter of the invention is a refrigeration appliance, in particular a household refrigeration appliance, with at least one storage chamber, a variable speed compressor for cooling the storage chamber, and a control unit for regulating the rotational speed of the compressor on the basis of a temperature measured in the storage chamber, which is configured and in particular is programmed to carry out the method described above.
A further subject matter of the invention is a computer program product with program code means that enable a computer to carry out the method described above or to operate as a control unit in the refrigeration appliance described above. In particular, the computer program product can be present as memory content of a microprocessor system or, in a form detached from the microprocessor system, on a data carrier.
Further features and advantages of the invention will emerge from the description of exemplary embodiments provided below, with reference to the attached drawings, in which:
Here, the evaporator 6 is shown as a no-frost evaporator in an evaporator chamber 8 separated from the storage chamber by an intermediate wall 7. Here, a defrost heater 9 can be formed by a heating rod, which is mounted on an underside of the block-shaped evaporator 6 and heats said evaporator by physical contact, radiation and/or convection during defrosting. A passage 13 is provided at the bottom of the evaporator chamber 8, in order to drain condensation water from the evaporator 6 to the outside, typically into an evaporation pan 14 in the machine compartment 4.
A control circuit 10, typically a microprocessor system that controls the operation of the compressor 5 and the defrost heater 9, can be placed at any suitable place on the carcass 1. The control circuit 10 is connected to an internal temperature sensor 11 for detecting the temperature of the storage chamber 3; furthermore, an ambient temperature sensor 12 for detecting the ambient temperature can be connected to the control circuit 10.
During normal operation, the control circuit 10 runs through a loop at regular time intervals, of which the first step S1, in the representation in
In step S4, the internal temperature Tin is compared with a second limit temperature T2, and in the event of T2 being exceeded, the rotational speed nt is decremented in step S5. The step sizes can be the same in step S3 and S5, but do not have to be. Likewise, the second setpoint temperature T2 can be identical to the setpoint temperature, but typically lies slightly higher, so that T1 and T2 define a temperature interval of a few degrees wide, within which the rotational speed nt is not changed.
In step S6, the difference between the instantaneous rotational speed nt of the compressor 5 and an initial value n0 is added to a control variable Int. Since, as the thickness of a layer of frost on the evaporator 6 increases, the compressor rotational speed needed to keep the storage chamber 3 at the setpoint temperature rises, this difference tends to assume values that are all the more positive, the longer it has been since the last defrosting procedure, meaning that the control variable Int rises over time.
As long as it is determined in step S7 that the control variable Int has not yet exceeded a threshold value thr, the method returns to the beginning, and the loop of steps S1 to S6 is repeated.
By contrast, if the threshold thr is exceeded, then the control circuit 10 switches off the defrost heater 9 and the compressor 5, in order to defrost (S8) the evaporator 6.
Following successful defrosting, the control variable Int is reset (S9) to a starting value that is lower than thr, typically to zero, and the compressor 5 is returned to operation.
The rotational speed when resuming operation can be a fixed standard value; it is also conceivable to resume operation with the rotational speed at which it was canceled in order to perform the defrosting. In the latter case, the rotational speed is usually higher than required to keep the storage chamber 3 at the setpoint temperature during continuous operation; however, this is also expedient in order to remove the heat, which has entered during the defrosting, from the storage chamber 3 again in a short period of time.
The temperature Tin of the storage chamber 3 is measured in step S10 and then compared with T1 in step S11. Due to the preceding interruption of the cooling operation and the unavoidable ingress of heat due to the defrosting, the temperature Tin will lie above T1 immediately after the resumption of the operation of the compressor, meaning that the steps S10, S11 are repeated until T1 is exceeded. If, as described above, the restart rotational speed of the compressor 5 has with certainty been chosen to be higher than necessary for maintaining the setpoint temperature, then it is sufficient to repeat the steps S10, S11; otherwise, it can be provided that the rotational speed is increased (S12) incrementally for as long as T1 has not yet been reached. In either case, at the point in time at which Tin falls below T1, the rotational speed nt is higher than necessary for maintaining the setpoint temperature.
Furthermore, the temperature Tin is also measured (S13) after falling below T1, and is compared (S14) with T1. If it remains below T1, then each time step S15 is repeated the rotational speed nt of the compressor 5 is decremented; additionally, a flag Fl− is set in order to indicate that T1 has been fallen below after restarting the compressor 5.
The consequence of decrementing the rotational speed nt is that T2 is exceeded again, sooner or later. As soon as this is identified in step S16, a second flag Fl+ is set (S17) in order to indicate the exceeding, and the rotational speed nt is incremented again. As soon as it is identified in step S18 that both flags Fl−, Fl+ are set, the loop of steps S13-S8 is canceled.
The rotational speed nt set at this point in time is specified as initial value n0 in step S19, after which the method returns to normal operation, i.e. the loop of step S1 to S7.
Since, in this way, a slightly lower value is chosen for n0 than is necessary to maintain the setpoint temperature, the difference nt−n0 is more often positive than negative during normal operation. This ensures that the control variable Int rises in the long term, and that sooner or later a new defrosting procedure is triggered. The faster that frost builds up on the evaporator 6, and for this reason the rotational speed nt is raised, the faster that the variable Int rises, and the faster that defrosting takes place once more.
This is followed by a step S20 of measuring the ambient temperature Tout with the aid of the sensor 12. A function F, which assigns a rotational speed of the compressor 5 to a measured ambient temperature Tout in each case, is stored in the control unit 10 in the form of a lookup table or a calculation rule. On the basis of this function F and the measured temperature Tout, an appropriate initial value n0 for the rotational speed when restarting the compressor 5 after the defrosting is specified in step S21. The function F can be defined such that it assigns each value of the ambient temperature Tout precisely the rotational speed that would be produced in stationary operation with a frost-free evaporator 6 for the ambient temperature in question when the steps S1-S5 described above are carried out repeatedly; in this case the compressor could theoretically run for any given length of time without defrosting, if the door 2 is not opened and also no moisture enters the storage chamber 3 in other ways that could condense as frost on the evaporator.
It is also conceivable, however, as described above in connection with
The same effect could also be achieved by the threshold value thr being reduced in a time-dependent manner, e.g. by a step of decrementing thr being added into the loop S1-S7.
After specifying the initial value n0, the temperature Tin of the storage chamber 3 is detected; this step is identical to the step S1 from
If the threshold value thr has not yet been reached in step S7, then a first variant of the method returns to step S1, in order once again to measure the temperature Tin, so that after repeatedly running through the loop S1-S7 the control variable Int approximates the integral
where n0=F(Tout(t0)), i.e. is the value of F that corresponds to the temperature Tout at the point in time to of restarting operation of the compressor.
If the ambient temperature decreases or increases during an operating phase of the compressor 5, then this leads to a reduction or increase in the rotational speed nt over steps S2 or S4. A reduction would have the consequence that the control variable Int rises more slowly than if the ambient temperature were to remain the same, and that consequently a defrosting procedure is delayed, even if the frost on the evaporator 6 has already reached a thickness at which it would make sense to perform a defrosting; conversely, an increase in the ambient temperature can trigger a premature defrosting. In order to avoid this, if the threshold value thr has not yet been reached in step S7, according to a second variant, the method jumps back to step S21, i.e. the ambient temperature Tout is measured, and n0 is updated on the basis of the measured temperature: n0(t)=F(Tout(t)), where t is the current point in time in each case. In this way, the time period between two defrosting procedures can be made independent of fluctuations in the ambient temperature Tout.
| Number | Date | Country | Kind |
|---|---|---|---|
| 102018221328.3 | Dec 2018 | DE | national |
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/EP2019/083595 | 12/4/2019 | WO | 00 |
