1. Field of the Invention
The present invention relates to a method for controlling the temperature inside a cavity of a cooling appliance provided with a temperature sensor inside the cavity and with an actuator to adjust the cooling capacity of the appliance. With the term “actuator” we intend all the actuators of the cooling appliance (compressors, dampers, valves, fans, etc.) which are used by the control system of the appliance for maintaining certain conditions in the cavity as set by the user, i.e. to adjust the cooling capacity of the appliance.
2. Description of the Related Art
Traditionally the temperature inside a refrigerator cavity is controlled by comparing the user set temperature with a measured temperature coming from a dedicated sensor. The user set temperature is converted into a Cut-off and Cut-On temperature and the measured temperature is compared to these two values in order to decide the compressor state (on/off or speed thereof in case of variable speed compressor) according to a so-called hysteresis technique. A similar approach is also used to generate over temperature alarm messages: the measured probe temperature (and some related quantities such as its derivative vs. time) is compared with a set of predetermined values and, based on the comparison, a warning or alarm message is generated. The drawbacks of this kind of known solutions are related to the fact that the look-up tables and predetermined values are the result of a compromise among all the possible work conditions. The result is a poorly controlled food temperature in response to different external temperatures, different load conditions and possible non-coherent alarm indications (false alarms or non-signaled alarms).
An object of the present invention is to provide an estimation of the average food temperature inside a freezer or refrigerator cavity with the use of a single temperature sensor inside this cavity. This estimation has two different main purposes. The first one is to contribute at the food preservation performances of the refrigerator by providing the appliance control algorithm with a temperature that is closer to the actual food temperature than the rough ambient temperature coming from the sensor inside the cavity. The second one is to minimize the risk of a false over temperature warning messages or undetected over-temperature conditions.
In a preferred embodiment, the present invention teaches the use of an estimation algorithm able to estimate the average food temperature inside a refrigerator cavity or in a special part of the cavity (drawer, shelf . . . ). This is done with the use of a single temperature sensor inside the cavity. According to the invention, the temperature coming from this sensor is correlated with the actuators state trends, these actuators being for example: the compressor, the damper which modulates the air flow between the freezer and the refrigerator compartments (in case of no-frost refrigerators), the fan, the heater for defrosting the evaporator or combination thereof. This correlation allows the conversion of the measured probe temperature into the most probable value of the food temperature.
In the following description we make reference to the appended drawings in which:
According to one aspect of the present invention, the correlation or conversion from the measured temperature (inside the cavity) and the estimated food temperature are done according to a “thermal flux” principle. The temperature difference or gradient ΔT between two points inside a cavity depends on the heat transfer coefficient G between these two points and the heat flow rate Q (thermal flux) passing from one point to the other. An approximated description of this phenomenon can be given by the following formula:
The estimation algorithm according to the present invention is based on this formula. We define the temperature difference ΔT as the difference of temperatures between two particular points inside the cavity: PS and PF.
PS is the point inside the cavity where the temperature sensor S is placed. PF can be chosen as the point inside the refrigerator having the temperature equal to the overall average food temperature or the temperature of the food that has to be monitored or controlled. If we indicate the temperature in correspondence of the point PS as MT (Measured Temperature) and the temperature at the point PF as FT (Food Temperature), we obtain:
The sensor S directly measures MT, 1/G is a parameter depending on the appliance and on the considered load condition (food type and position). Each load condition and each sample of appliance provides a specific value for G. An average value for this parameter must be found during the design phase.
The flow rate is strictly dependent on the temperature of the cold source of the cavity (i.e. the evaporator). If such temperature cannot be measured (a typical situation where this invention can be used), the value of Q can be estimated by processing the actuators (fans, compressor, damper) trends. The quantity
is defined as Offset Temperature OT:
According to this estimation, the food temperature can be described as:
FT=MT−OT (eq. 5)
One aspect of this invention is to provide a method for determining the quantity OT so that, according to the eq.5, an estimation of the food temperature FT can be obtained.
In order to describe the method used for the estimation of the food temperature, an experimental prototype of a no frost bottom mount refrigerator/freezer will be used. A schematic representation of this refrigerator/freezer is shown in
OT=f(Actuators(t)).
In the specific case this function can be rewritten as:
OT(t)=f(Compressor(t, t0),Damper(t, t0))
The terms Compressor(t,t0) and Damper(t,t0) represent the average trend of the status of the compressor and the damper vs. time. One of the most common ways to compute this value is the use of IIR (infinite impulse response) filters. According to this solution, these two quantities will be obtained with the following formulas:
Compressor(t,t0)=(1−α)·Compressor(t−Dt,t0)+α·C(t) (eq. 6)
Damper(t, t0)=(1−β)·Damper(t−Dt, t0)+β·D(t) (eq. 7)
C(t) and D(t) represent the status of the compressor and of the damper at the instant t. D=0 represents damper closed, D=1 represents damper open. C=0 represents compressor “off”, C=1 represents compressor “on”. It's important to remark that the specific case used to describe the invention takes in consideration an ON/OFF compressor and an ON/OFF damper. The concepts and the technical solutions according to the invention can be extended to the case of “continues” actuators without limitations. The parameters α and β (inside the range 0-1) determine the “speed” of the filters in reaching the average value. The closer the value to 1, the faster the filter, which is good, but this allows the filter to be too sensitive to the disturbances (door opening, food introductions, defrost, etc.). Moreover the value of these parameters should be small enough to filter the effects of the actuators cycling set by the temperature control.
As an example, we can consider the function f as linear. In this case we have:
OT(t)=α·Compressor(t,t0)+b·Damper(t,t0)+c (eq. 8)
In the design phase, the value of a, b, c can be obtained through a well-defined set of experimental tests on the specific cooling appliance. These tests must be executed by measuring the quantities OT(t), Compressor(t,t0) and Damper(t,t0) in the most significant work conditions, considering different external temperatures, different load quantities inside the refrigerator and different load positions. The parameters a, b, c can be obtained from the experimental data with the common identification techniques, for example, the least square method is suitable for this purpose.
The food temperature estimation can be obtained from the offset temperature according to the eq.5. Most of the time the measured temperature must be pre-filtered with a low pass filter to be used for this purpose. This has to be done because the measured temperature is a measure of the air temperature close to the sensor S. This gets the dynamics of MT too “fast” to be taken as it is in the equation 5. For this reason a low pass filter LPF can be used before adding the measured temperature to the offset temperature in the eq.5.
As mentioned at the beginning of the description, the estimation of OT can be used with mainly two purposes:
1. To provide a more precise food temperature control.
2. To provide a more reliable over temperature alarm message.
Another purpose of the present invention is the generation of coherent over temperature alarms or warnings.
It is clear that the present invention provides a more precise food temperature control and a more reliable over temperature warning message. This is done by converting the rough temperature coming from the temperature sensor in the refrigerator or freezer cavity into an estimation of the average temperature of the food stored in the cavity. One of the main advantages in using this technical solution comes from the fact that it doesn't require the use of specific temperature sensors. The conversion can be done by using the temperature sensor that is traditionally present in the refrigerator cavity and by correlating this measured value with the actuator trends without the addition of further dedicated sensors.
Number | Date | Country | Kind |
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05108205.5 | Sep 2005 | EP | regional |