[0001] The present invention relates to a method of operation of a household refrigerating
apparatus and to a household refrigerating apparatus implementing said method.
[0002] It is worth stating beforehand that the term household refrigerating apparatus as
used in the present description and in the appended claims refers to those refrigerating
apparatuses which comprise a first cooled compartment which is typically kept at a
temperature between 0 °C and 12°C (commonly called refrigerator compartment) and a
second cooled compartment which is typically kept at a lower temperature between -12
°C and -35 °C (commonly called freezer compartment).
[0003] More in particular, the present invention addresses all those refrigerating apparatuses
which are commonly referred to as no-frost, wherein the cooling of the foodstuffs
stored in both cells is ensured by cold air conveyed therein by a forced ventilation
system; the circulating air is cooled by an evaporation-type exchanger, or evaporator,
by thermal exchange with a colder refrigerating fluid circulating within a refrigerating
circuit that comprises at least one compressor, one condenser and one expansion valve.
[0004] A household refrigerating apparatus of the no-frost type as described above typically
produces some operating noise mainly caused by two components: the compressor and
the fan of the forced ventilation system; of these two components, the compressor
is certainly the one which is more noisy (in terms of noise perceived within the apparatus
installation environment), since the fan is arranged inside the apparatus, near the
channels that circulate the cold air into both compartments.
[0005] As a matter of fact, when the apparatus is operating normally, the compressor starts
whenever cold air must be produced in order to maintain the preset temperature inside
the cells: tests carried out have shown that the frequency of compressor intervention
in a refrigerating apparatus placed in an environment at 25°C with the cell access
doors closed is approximately thirty minutes of continuous operation per hour.
[0006] It can therefore be easily understood that the frequent activation of the compressor
represents a source of disturbance, in particular in all those situations where the
need of reducing noise is particularly felt, e.g. during the night.
[0007] Some solutions have been conceived in the art, such as the one described in patent
KR2001-0081331 to SAMSUNG ELECTRONICS CO LTD, wherein, in order to reduce the noise produced by
the apparatus in predetermined time periods, the compressor operating parameters are
changed by using a timer or a brightness sensor.
[0008] However, this solution is not optimal, in that the compressor must still be activated,
although at lighter operating conditions, in order to keep the compartments at a preset
operating temperature, and this prevents total or almost total silence from being
obtained (as required, for example, when a refrigerating apparatus is to be installed
near a bed in a one-room or two-room apartment).
[0009] The present invention aims at overcoming these and other drawbacks of the systems
known in the art through a method of operation for a household refrigerating apparatus
according to claim 1.
[0010] The present invention also relates to a household refrigerating apparatus implementing
said method.
[0011] The present invention is based on the idea of using the freezer compartment (i.e.
the one kept at a lower temperature than the refrigerator compartment) as a tank from
which cold air can be taken and conveyed into the refrigerator compartment (operating
at a higher temperature) in order to keep the latter at a preset and possibly constant
temperature while keeping the compressor off, after the freezer compartment has been
brought to a temperature below its normal operating temperature, which condition does
not affect the quality of preservation of the foodstuffs stored in such compartment.
[0012] This advantageously allows the compressor to stay off for a long time, approximately
three to eight consecutive hours, thereby eliminating any noise related to compressor
operation.
[0013] Further advantageous features will be set out in the appended claims, which are intended
as an integral part of the present text.
[0014] These features as well as further advantages of the present invention will become
apparent from the following description of an embodiment thereof as shown in the annexed
drawings, which are supplied by way of non-limiting example, wherein:
Fig. 1 shows a household refrigerating apparatus;
Fig. 2 is a flow chart of the method according to the present invention;
Fig. 3 shows the time trend of the temperatures in the refrigerator compartment and
freezer compartment during an operating cycle according to the present invention.
[0015] Fig. 1 shows a no-frost refrigerating apparatus 1 as described above; it comprises
a refrigerator compartment 2 and a freezer compartment 3, in fluidic communication
with the evaporator 4 of the refrigerating circuit and a fan 5; the air circulated
by the fan 5 laps the evaporator 4, thereby being cooled, and is then admitted into
the freezer compartment 3 to refrigerate it, wherefrom it subsequently enters the
refrigerator compartment 2 through a channel 6 in order to cool and dehumidify this
compartment as well; circulation may be ensured in this case by a second fan 12 arranged
at the end of the channel 6; it must however be specified that the second fan 12 is
optional, in the sense that it may be omitted.
[0016] The air flow coming from the freezer compartment 3 and directed to the refrigerator
compartment 2 is regulated by means of an on-off valve 8 installed in the channel
6 (commonly called "damper" by those skilled in the art), which is shown herein in
its simplest form, i.e. a gate that shuts off the cross-section of the channel 6.
[0017] The position of the on-off valve 8 may vary depending on specific implementation
requirements; in general, it may be located anywhere along the channel 6 that carries
the air from the freezer compartment 3 to the refrigerator compartment 2: for example,
if the second fan 12 is not provided, the on-off valve may be installed in its place,
i.e. in that part of the channel 6 which is closest to the refrigerator compartment
2.
[0018] The forced air circulation is conceived in a manner such that the air exiting the
refrigerator compartment 2 flows back into the freezer compartment 3 through an additional
return duct (not shown for clarity), which puts the refrigerator compartment 2 in
fluidic communication with the freezer compartment 3, so that the air is cooled down
again by the evaporator 4 and a new cycle is started.
[0019] Of course, an on-off valve may be installed on the air return duct as well; however,
the characteristics of said return duct and of its on-off valve are not important
for understanding the present invention and may vary depending on specific construction
requirements.
[0020] The evaporator 4 belongs to a refrigerating circuit of a per se known type, which
also includes a compressor 9, a throttling valve 10 and a condenser 11, with all the
respective connection pipes (indicated by means of a dashed-dotted line in the drawing).
[0021] Fig. 1 also shows the shelves 13 typically provided in the compartments 2 and 3,
the doors 14 and 15 for closing the latter, and two temperature sensors 17 and 18
respectively arranged in the refrigerator compartment 2 and in the freezer compartment
3 and adapted to detect the air temperature, respectively T
f and T
c, within said compartments.
[0022] The fans 5 and 12 and the on-off valve 8 are driven each by a respective electric
motor (not shown) controlled by a control unit (not shown) which receives the temperature
data read by the sensors 17 and 18 and controls the refrigerating cycle accordingly,
e.g. by controlling the operation of the compressor 9.
[0023] In general, of course, the presence of an additional compartment will not affect
the method of operation of the refrigerating apparatus 1.
[0024] During the normal operating cycle, the control unit is inputted the temperatures
T
f and T
c respectively detected by the sensors 17 and 18 and then controls the compressor 9,
the fans 5 and 12 (if present) and the on-off valve 8 accordingly so as to keep the
temperatures in both compartments 2 and 3 within preset values: the average temperature
in the refrigerator compartment 2 can typically be set between 2°C and 12°C, whereas
the average temperature in the freezer compartment 3 can be set between -18°C and
-26°C, in both cases with an oscillation of about 4°C around the set average value.
[0025] More in detail, if during a normal operating cycle the sensors 17 and 18 detect a
temperature rise in the refrigerator compartment 2 or in the freezer compartment 3,
the compressor 9 will be started, the fans 5 and 12 will be turned on, and the on-off
valve 8 will be opened (completely or partially), so as to cool down the freezer compartment
3 and partialize the cold air flow directed therefrom towards the refrigerator compartment
2, thereby adjusting the temperature thereof.
[0026] In this regard, it should be pointed out that during the normal operating cycle the
fans 5 and 12 are turned on and the on-off valve 8 is made to open the channel 6 only
when the compressor 9 is operating; as soon as the latter is switched off, the fans
5 and 12 will be deactivated and the on-off valve 8 will close the channel 6.
[0027] The method of operation according to the present invention is based on the execution
of at least the following steps:
b) turning off the compressor 9;
c) taking a cold air flow from the freezer compartment 3 and conveying it into the
refrigerator compartment 2, so as to keep the temperature of the latter within predefined
minimum and maximum threshold values Tfmin and TfMAX,
and wherein the time interval during which the compressor 9 is off is such that the
temperature in the freezer compartment 3 does not exceed a predefined threshold value
T
sup.
[0028] It is thus possible to adjust the temperature of the refrigerator compartment 2 by
taking cold air from the freezer compartment 3 without having to use the compressor
9, thereby making the refrigerating apparatus 1 extremely quiet.
[0029] Taking a cold air flow from the freezer compartment 3 necessarily implies that the
temperature of the latter will rise; for this reason, a maximum threshold temperature
may be set above which the compressor 9 will be turned on, thus ending the quiet operation
mode.
[0030] Aiming at extending the period of quiet operation (i.e. with the compressor 9 switched
off) of the refrigerating apparatus 1, the method provides for carrying out, prior
to step b) as previously described, a step a) consisting of bringing the temperature
of the freezer compartment 3 down to a value T
inf which is lower than the normal operating temperature T
cn; this is made possible by the fact that a decrease in the temperature inside the
freezer compartment 3 below the normal operating temperature T
cn will cause no damage to the foodstuffs stored therein, while at the same time allowing
the freezer compartment 3 to cool the air directed to the refrigerator compartment
2 for quite a long time before the temperature rising inside the freezer compartment
requires that the compressor 9 be turned on again.
[0031] More specifically, step a) is effected by keeping the compressor 9 on for a longer
time than normal: for example, if in normal operation the compressor stays on for
approximately thirty minutes, in this case it may be kept on continuously for a period
which may vary preferably between sixty and one hundred and eighty minutes, and anyway
in a manner such that the temperature in the freezer compartment 3 drops below the
normal operating temperature T
cn (typically T
cn=-18°C), e.g. until a value Tinf in the range of -23°C to -26°C is reached, i.e. five
to eight Celsius degrees less than temperature T
cn.
[0032] In this respect, it must be pointed out that step a) may be effected by using as
a control quantity either the operating time of the compressor 9 or the temperature
reached in the freezer compartment 3: such quantities are related in a proportional
manner to each other, i.e. the longer the continuous operation of the compressor 9,
the lower the temperature reached in the freezer compartment 3. For the purposes of
the present invention, either solution may be adopted for executing step a), i.e.
it is possible to choose whether the compressor 9 should operate for a preset period
of time or, alternatively, until it is detected that a temperature threshold has been
reached in the freezer compartment 3.
[0033] After step a) has been carried out, independently of the control quantity employed
(operating time or temperature in the freezer compartment 3), the compressor 9 is
turned off, thereby starting the quiet operation of the refrigerating apparatus 1:
in this situation, the sensors 17 and 18 detect the temperatures T
f and T
c in both compartments 2 and 3 at predefined time intervals (or continuously) and send
the data obtained to the control unit.
[0034] Assuming that the doors 14 and 15 stay closed, the two compartments 2 and 3 will
remain at optimal temperatures for a certain period of time, thanks to the gaskets
and insulation provided.
[0035] Due to the thermal exchange with the environment surrounding the refrigerating apparatus
1, however, the temperatures in both compartments 2 and 3 will tend to rise again.
[0036] In particular, after a certain time has elapsed, the temperature T
f in the refrigerator compartment 2 will rise above a set threshold value T
fMAX (e.g. T
fMAx=5°C); on the other hand, the temperature T
c in the freezer compartment 3, which during step a) was brought much below the normal
operating temperature (to value T
inf), will still remain for a long time at a value below a predefined threshold value
T
sup, which may be chosen to be equal to the normal operating temperature T
cn (e.g. T
sup=T
cn=-18°C).
[0037] When the control unit detects that the preset threshold temperature T
fMAX in the refrigerator compartment 2 has been exceeded, it opens the on-off valve 8
and turns on the fan 5 and (if present) also the second fan 12 in order to carry out
step c), wherein a cold air flow is taken from the freezer compartment 3 and is conveyed
into the compartment at the higher temperature, i.e. the refrigerator compartment
2, until the latter reaches again a preset temperature, e.g. equal to the lower threshold
value T
fmin, without the help of the compressor 9, which is left off.
[0038] Step c) may be carried out multiple times, at least as long as the temperature inside
the freezer compartment 3 remains below the predefined maximum threshold value T
sup.
[0039] In this regard, it should be noted that step c) may be effected either continuously
or through a certain number of repetitions; in the former case, the on-off valve 8
will always stay at least partially open, and the fans 5 and 12 (if present) will
be turned on (possibly at a variable revolution speed) based on the temperature values
detected in the refrigerator compartment 2: if the temperature rises, the fan 5 and/or
12 will be turned on and possibly the on-off valve 8 will open a larger section of
the channel 6 (in order to let more cold air flow therethrough) for the purpose of
lowering the temperature in the refrigerator compartment 2; when the temperature in
the latter becomes optimal, the fan 5 and/or 12 will be turned off (or, likewise,
the revolution speed thereof will be reduced to the minimum), but the on-off valve
8 will stay open.
[0040] As a preferable alternative, step c) is effected by repeating the steps of opening
the on-off valve 8 and activating the fan 5 and/or 12 until the threshold temperature
T
fmin is reached in the refrigerator compartment 2, which condition will be followed by
the fan being turned off and the on-off valve 8 being closed as soon as the temperature
in the refrigerator compartment 2 reaches a predefined value.
[0041] In any case, when the sensor 18 detects that the temperature inside the freezer compartment
3 has reached or exceeded a maximum threshold value (T
c≥T
sup), the quiet operation cycle will end and the compressor 9 will be turned on again.
[0042] It must be pointed out that in optimal conditions, i.e. when the refrigerating apparatus
1 is placed in an environment at approximately 10°C and the doors 14 and 15 are not
open, by setting the threshold values as follows:
Tinf -24°C
Tsup= -18°C
Tfmin= 0°C
TfMAX= 4°C
it will be possible to leave the compressor 9 off for periods of time as long as about
eight consecutive hours, thus attaining a substantial improvement over prior-art solutions,
wherein the compressor 9 had to be turned on more often, although at lighter operating
conditions.
[0043] Even in less favourable conditions, e.g. when ambient temperature is 35°C, it has
been discovered that this solution allows to leave the compressor 9 off for a time
longer than three consecutive hours, thus leading to a definite improvement over prior-art
systems.
[0044] Of course, repeated openings of the door 15 of the freezer compartment 3 may heavily
affect the time of operation with the compressor 9 off. However, it is often desirable
that the apparatus be quiet at nighttime, when the compartments of the refrigerating
apparatus 1 are accessed relatively seldom (or never at all), so that the behaviour
of a refrigerator implementing such a method is deemed to be satisfactory.
[0045] The flow chart of the method of operation according to the present invention is shown
in Fig. 2: the operating cycle starts with a first step of turning on the compressor
9, which is kept on for a predefined time (condition TIMER END) or until the temperature
in the freezer compartment T
c drops and becomes substantially equal to the threshold temperature T
inf (condition T
c = T
inf), after which the compressor 9 is turned off and the on-off valve 8 is closed.
[0046] The temperature T
f in the refrigerator compartment 2 is then detected: as long as it remains below the
maximum threshold T
fMAX, no action will be taken.
[0047] When the temperature T
f rises above the maximum threshold value T
fMAX, the temperature T
c in the freezer compartment 3 will be verified: if this is lower than the upper threshold
value T
sup, the on-off valve 8 will be opened and the fan 5 or the second fan 12 (if present)
will be turned on in order to direct a cold air flow from the freezer compartment
3 to the refrigerator compartment 2, until the temperature T
f in the refrigerator compartment 2 becomes equal to the lower threshold value T
fmin, at which the on-off valve 8 will be closed and the fan(s) 5 and 12 will be turned
off.
[0048] If, on the contrary, after the temperature T
f has risen above the maximum threshold value T
fMAX, it is verified that the temperature T
c in the freezer compartment 3 is higher than the upper threshold value T
sup, then the cycle will be considered to be finished and the compressor 9 will be turned
on, the on-off valve 8 will be opened, and the fans 5 and 12 will be turned on in
order to restore the temperatures of the normal operating cycle.
[0049] According to an advantageous variant, the threshold temperatures set for the refrigerator
compartment 2 are equal to each other, i.e. T
fmin is equal to T
fMAX.
[0050] In such a case, the system will still operate as described above, except that the
temperature in the refrigerator compartment 2 will always be kept substantially around
a single predefined value, i.e. T
fmin=T
fMAX.
[0051] In this regard, it must be pointed out that this variant also provides for changing
the temperature thresholds of the refrigerator compartment 2 as the compressor 9 is
operating continuously during step a): in normal operation, as aforementioned, the
cooling of the refrigerator compartment 2 is controlled in a manner such that the
temperature of the latter oscillates by about 4°C around a set average value; in this
variant of the method, instead, during step a) the temperature of the refrigerator
compartment 2 is already set to the value T
fmin=T
fMAX, i.e. the temperature threshold value to be maintained in the course of the subsequent
step c), so that when the latter starts the temperature in the refrigerator compartment
2 will have already reached the value to be maintained when operating with the compressor
9 off.
[0052] Said temperature value T
fmin=T
fMAX is reached and maintained in the refrigerator compartment 2 by turning on the fans
5 and/or 12 and by opening and closing the on-off valve 8, so as to deliver a variable
cold air flow into the refrigerator compartment 2 in order to bring it to the desired
temperature T
fmin=T
fMAX and keep it at that temperature.
[0053] It is important to underline that the solution provided by this variant allows to
extend the time during which the compressor 9 stays off and cold air is taken from
the freezer compartment 3; in fact, the more the instantaneous temperature inside
the refrigerator compartment 2 is kept constant, the less thermal energy must be used
for keeping the average temperature constant, and hence the longer the time that the
compressor 9 will stay off.
[0054] This solution is shown in Fig. 3, where time (expressed in hours) is indicated on
the abscissas and temperature is indicated on the ordinates; the upper bundle of curves
C1 shows the temperature trend in various points inside the refrigerator compartment
2, while the lower bundle of curves C2 shows the temperature trend in various points
inside the freezer compartment 3.
[0055] As can be seen, in normal operation an operating cycle is activated which comprises
the steps of the method according to the present invention: during the above-described
step a), the compressor 9 is turned on for a period of time of approx. 80 minutes,
during which the temperature in the freezer compartment 3 drops from an initial value
(in the steady state of normal operation) of approx. -18°C to a value T
inf of approx. -25°C, as shown by the trend of the bundle of curves C2. Within this period
of time, the value of the temperature in the refrigerator compartment 2 also drops
from a higher initial value to settle around a value T
fMAX of approx. 4°C, as shown by the trend of the bundle of curves C1, in accordance with
the above discussion.
[0056] When such values are reached, step b) of the above-described method is carried out,
wherein the compressor 9 is turned off and the on-off valve is closed.
[0057] Subsequently, for a period of about four hours, the temperature in the refrigerator
compartment 2 is kept substantially constant, being (T
fmin=T
fMAX) approximately equal to 5°C, by implementing step c) of the method, i.e. by taking
cold air flows from the freezer compartment 3, the temperature of which, as shown
by the trend of the bundle of curves C2, rises up to the threshold value T
sup, at which step c) will end and the normal operation of the refrigerating apparatus
1 will be resumed.
[0058] It should be noted that the temperature T
inf may be, in general, any temperature lower than T
cn, although the best results are attained by setting it to a value lower than the temperature
T
cn by three to ten Celsius degrees, in particular six Celsius degrees.
[0059] More specifically, the threshold value T
fmin varies between 0°C and 2°C, the threshold value T
fMAX varies between 4°C and 6°C, the threshold value T
sup varies between -20°C and - 16°C, and the threshold value T
inf varies between -24°C and -30°C, the normal operating temperature of the freezer compartment
3 being approx. -18°C.
[0060] As concerns the command issued by the user in order to start the method of operation
described so far, three different conditions may take place, respectively coinciding
with manual, semi-automatic and automatic operation.
[0061] In the first case (manual control), the user sets the method starting instant (coinciding
with the beginning of step a)) by simply pressing a button specifically intended for
that purpose.
[0062] In the second case (semi-automatic operation), the user sets a time interval after
which the refrigerating apparatus 1 will have to start operating in quiet mode; for
example, the user may want the refrigerating apparatus 1 to start operating in quiet
mode after four hours, which coincides, as described above, with the fact that the
compressor 9 will have to stay off after the selected time interval; in this case,
the control unit of the refrigerating apparatus 1 includes a timer and controls the
execution of step a) at a time preceding the time chosen by the user, so that said
step will be completed at the end of the selected time interval. It must be pointed
out that this mode of operation is particularly feasible when the control quantity
in use for step a) is the continuous operating time of the compressor 9, as opposed
to the temperature reached in the freezer compartment 3.
[0063] In the third case (automatic operation), the user sets a time at which the quiet
operation mode will have to start (i.e. steps b) and c)): in this case, the control
unit includes a suitable clock or timer, and controls the execution of step a) in
a manner such that it will end at the time set by the user. In this case as well,
it will be preferable to use the operating time of the compressor 9 instead of the
temperature reached in the freezer compartment 3 as a control quantity for step a).
[0064] The present invention also relates to a refrigerating apparatus 1 of the type shown
in and described with reference to Fig. 1, which implements the method according to
the present invention.
[0065] As a variation, it should be pointed out that, in the refrigerating apparatus 1,
the shelves 13 may be equivalently replaced with drawers or compartments; likewise,
the on-off valve 8 may be of any kind (e.g. butterfly, sector or the like), provided
that it is suitable for intercepting the channel 6 in order to allow the air flow
carried therethrough to be adjusted.
[0066] In turn, the channel 6 may be arranged differently than illustrated herein, for example
by connecting different points of the compartments 2 and 3, without however departing
from the scope and objects of the present invention.
[0067] The on-off valve 8 may then be placed anywhere along the channel 6, e.g. even in
a position adjacent to the refrigerator compartment 2.
[0068] Finally, the fans 5 and 12 may be arranged differently than illustrated herein and,
as aforementioned, the second fan 12 may be omitted.
1. Method of operation of a household refrigeration apparatus (1), of the type comprising
at least a first (2) and a second (3) compartments for foodstuff storage, and a refrigerating
circuit for cooling said compartments (2,3), wherein the refrigerating circuit comprises
at least one compressor (9) and the compartments are kept at different temperatures,
the first compartment (2) being a refrigerator compartment (2) kept at a higher temperature,
and the second compartment (3) being a freezer compartment (3) kept at a lower temperature,
characterized by comprising at least the following steps:
b) turning off the compressor (9) for a time interval;
c) taking a cold air flow from the freezer compartment (3) and conveying it into the
refrigerator compartment (2), so as to keep the temperature of the latter within a
temperature range defined by a first and a second threshold values (Tfmin,TfMAX),
and wherein said time interval during which the compressor (9) is off is such that
the temperature in the freezer compartment (3) does not exceed a third predefined
threshold value (T
sup).
2. Method according to claim 1, wherein step b) follows a step a) wherein the temperature
of the freezer compartment (3) is brought to a fourth threshold value (Tinf) which is lower than the normal operating temperature value (Tcn).
3. Method according to claim 2, wherein the normal operating temperature value (Tcn) of the freezer compartment (3) essentially matches said third threshold value (Tsup).
4. Method according to claim 2 or 3, wherein the fourth threshold value (Tinf) is lower than the normal operating temperature (Tcn) of the freezer compartment (3).
5. Method according to any of the preceding claims, wherein said first and second threshold
values (Tfmin,TfMAX) of the temperature in the refrigerator compartment (2) are substantially equal.
6. Method according to any of the preceding claims, wherein the step c) of taking a cold
air flow from the freezer compartment (3) and conveying it into the refrigerator compartment
(2) so as to keep the temperature of the latter within a temperature range defined
by a first and a second threshold values (Tfmin,TfMAX) is repeated several times.
7. Method according to any of the preceding claims, comprising the steps of:
- turning on the compressor (9) and keeping it on until the temperature (Tc) in the freezer compartment (3) reaches said fourth threshold value (Tinf) or for a predefined time interval;
- turning off the compressor (9);
- preventing air from passing between the refrigerator compartment (2) and the freezer
compartment (3);
- detecting the temperature (Tf) in the refrigerator compartment (2);
- comparing said temperature value (Tf) detected in the refrigerator compartment (2) with said second threshold value (TfMAX);
- if the temperature value (Tf) exceeds the maximum threshold value (TfMAX), the temperature (Tc) in the freezer compartment (3) is detected and compared with said third threshold
value (Tsup) and, if the temperature value (Tc) in the freezer compartment (3) is lower than said third threshold value (Tsup): the refrigerator compartment (2) is put in fluidic communication with the freezer
compartment (3), so as to transfer a cold air flow from the latter to the former,
thereby cooling the refrigerator compartment until the measured temperature reaches
said first threshold value (Tfmin) or until the temperature (Tc) in the freezer compartment exceeds the threshold value (Tsup);
- if the temperature value (Tf) exceeds the maximum threshold value (TfMAX), the temperature (Tc) in the freezer compartment (3) is detected and compared with said third threshold
value (Tsup) and, if the temperature value (Tc) in the freezer compartment (3) is higher than said third threshold value (Tsup): the compressor (9) is turned on.
8. Method according to any of the preceding claims, wherein said fourth threshold value
(Tinf) is lower than the normal operating temperature (Tcn) by a value between three and ten Celsius degrees, in particular six Celsius degrees.
9. Method according to any of the preceding claims, wherein the first threshold value
(Tfmin) varies between 0°C and 2°C, the second threshold value (TfMAX) varies between 4°C and 6°C, the third threshold value (Tsup) varies between -20°C and -16°C, the fourth threshold value (Tinf) varies between -24°C and -30°C, and the normal operating temperature of the freezer
compartment (3) is approximately -18°C.
10. Method according to any of the preceding claims, wherein the duration of step a) is
established as a function of a control quantity, such as the temperature in the freezer
compartment (3) or a time interval.
11. Method according to any of the preceding claims, wherein the first threshold value
(Tfmin) is equal to the second threshold value (TfMAX).
12. Method according to any of the preceding claims, wherein during step a) the refrigerator
compartment (2) temperature is brought to a value which is substantially equal to
the first threshold value (Tfmin).
13. Method according to any of the preceding claims, wherein the activation of step a)
of the method is controlled by the user.
14. Method according to any of claims 1 to 12, wherein the activation of step a) of the
method is controlled by a control unit of the refrigeration apparatus (1) depending
on an instant of activation of step b) chosen by a user, in a manner such that step
a) ends when step b) is activated.
15. Refrigeration apparatus (1) of the type comprising a first refrigerator compartment
(2) and a second freezer compartment (3), wherein at least the freezer compartment
(3) is in fluidic communication with an evaporator (4) of a refrigerating circuit
comprising at least one compressor (9), one throttling valve (10) and one condenser
(11), and wherein a forced circulation of air cooled by the evaporator is generated
in the freezer compartment (3) by at least one fan (5), said refrigerator compartment
(2) and said freezer compartment (3) being in fluidic communication with each other
by means of a channel (6) intercepted by an on-off valve (8), so that the refrigerator
compartment (2) is cooled by an air flow taken from the freezer compartment (3),
characterized in that
it implements the method according to any of claims 1 to 14.