JP2013242057A - Refrigerator - Google Patents

Abstract

PROBLEM TO BE SOLVED: To properly control cooling capability by quickly detecting change in the amount of objects stored in a refrigerator (load fluctuation).SOLUTION: A refrigerator includes a cooling fan 10 for supplying chilled air to a housing chamber, and a calculation control part 14 which detects rotation speed of the cooling fan 10 or an input current value and arithmetically operates the detection result. The change in wind channel resistance caused by the objects stored therein is calculated from the rotation speed of the fan motor or the input current, for estimating the amount of objects. The change in the amount of objects stored in the refrigerator (load fluctuation) is quickly detected, to properly control cooling capability. The temperature of the objects is kept at an optimum state, while keeping freshness excellently. The objects can be prevented from being excessively cooled, to reduce power consumption.

Description

  The present invention relates to a refrigerator provided with means for detecting the amount stored in a refrigerator inside, and more particularly to a refrigerator that controls the operation state in the refrigerator according to the amount stored in the refrigerator.

  In recent years, household refrigerators generally use an indirect cooling method in which cold air is circulated in the refrigerator with a fan. In a conventional refrigerator, the temperature in the refrigerator is kept at an appropriate temperature by controlling the temperature according to the detection result of the temperature in the refrigerator.

  For example, there is a refrigerator provided with a movable cold air discharge device as a refrigerator that keeps the inside temperature uniform (see Patent Document 1).

  FIG. 13: shows front sectional drawing of the refrigerator compartment of the conventional refrigerator described in patent document 1. As shown in FIG.

  As shown in FIG. 13, a movable cold air discharge device 102 provided in the refrigerator compartment 101 supplies cold air to the left and right to make the internal temperature uniform.

JP-A-8-247608

  However, even if the inside temperature is made uniform, the stored items are not always stored at the optimum temperature. This is because the refrigerator detects and controls the ambient temperature in the cabinet by the thermistor, and there is no means for directly detecting the temperature of the stored item. Therefore, a difference occurs between the ambient temperature in the storage and the actual temperature of the stored items.

  For example, in a transition period from immediately after the stored item to temperature stabilization, a temperature difference depending on the amount of stored item occurs between the detection temperature of the temperature detecting means arranged in the warehouse and the temperature of the stored item. The time required to reach the storage temperature varies depending on the amount of storage. Specifically, the cooling time is short when the storage amount is small, and the cooling time is long when the storage amount is large. In particular, when the storage amount is small, the cooling operation may be performed excessively, resulting in “too cold” storage.

  In addition, after a sufficient time has passed, the stored item keeps its temperature by its own heat capacity, so the larger the stored amount, the lower the temperature of the inside atmosphere. For this reason, the stored item becomes “too cold”, and the stored item cannot be cooled at an optimum temperature. Furthermore, during this time, the refrigerator performs cooling operation using excess power consumption.

  The present invention solves the above-described conventional problems, and the amount stored in the refrigerator is estimated in advance from information obtained from the rotational speed or current value of the fan motor that drives the cooling fan disposed in the refrigerator. Based on the above, it is intended to provide a refrigerator that has a high freshening function regardless of the storage state in the warehouse by controlling the operation state of the refrigerator, and that prevents “too cold” and suppresses power consumption. To do.

  In order to solve the above-described conventional problems, a refrigerator according to the present invention includes a storage chamber that is partitioned by a heat insulating wall and a heat insulating door and stores stored items, a cooler for cooling the storage chamber, and a storage chamber. A damper that controls the amount of cool air, a heat insulating door that covers the storage chamber, a door open / close detection means that detects opening and closing of the heat insulation door, a cooling fan that supplies the cool air to the storage chamber, and driving the cooling fan A fan motor; a detection unit that detects a rotation speed or a current value of the fan motor; and a calculation control unit that calculates a detection result of the detection unit, wherein the calculation control unit includes: The storage amount of the storage chamber is estimated based on the detection result and the detection result of the detection unit.

  Thereby, the fluctuation | variation of the air path resistance by a stored item is calculated from the rotation speed or input current of a fan motor, and a storage amount can be estimated.

  The refrigerator of the present invention detects the storage amount in advance and controls the operation state of the refrigerator based on the information, thereby enabling cooling suitable for the storage amount in the warehouse and realizing high freshness of stored items. In addition, power consumption can be suppressed by preventing the stored items from being “too cold”.

Side surface sectional drawing of the refrigerator in Embodiment 1 of this invention Control block diagram according to Embodiment 1 of the present invention (A) Air flow rate and static pressure / rotation speed characteristic diagram in Embodiment 1 of the present invention, (b) Speed and storage amount characteristic diagram in Embodiment 1 of the present invention Control flowchart according to Embodiment 1 of the present invention (A) Characteristic diagram of air volume and rotational speed including correction factor in Embodiment 1 of the present invention, (b) Characteristic diagram of rotational speed and storage amount including correction factor in Embodiment 1 of the present invention Control block diagram in Embodiment 2 of the present invention (A) Airflow and static pressure / input current characteristics in Embodiment 2 of the present invention, (b) Input current and capacity characteristics in Embodiment 2 of the present invention Control flowchart in Embodiment 2 of the present invention (A) Airflow and input current characteristic diagram including correction factors in Embodiment 2 of the present invention, (b) Input current and storage capacity characteristic diagram including correction factors in Embodiment 2 of the present invention Control block diagram in Embodiment 3 of the present invention (A) Air flow rate and static pressure / rotation speed characteristic diagram according to Embodiment 3 of the present invention, (b) Revolution speed and storage amount characteristic diagram according to Embodiment 3 of the present invention Control flowchart in Embodiment 3 of the present invention Front view of the main parts of a conventional refrigerator

  The first invention is a storage chamber that is partitioned by a heat insulating wall and a heat insulating door and stores stored items, a cooler for cooling the storage chamber, a damper that controls the amount of cold air to the storage chamber, A heat insulating door that covers the storage chamber; door opening / closing detection means that detects opening and closing of the heat insulating door; a cooling fan that supplies cool air to the storage chamber; a fan motor that drives the cooling fan; and a rotational speed of the fan motor Alternatively, it includes a detection unit that detects an input current and a calculation control unit that calculates the detection result of the detection unit, and the calculation control unit includes a detection result of the door opening / closing detection unit and a detection result of the detection unit. Based on this, the storage amount of the storage chamber is estimated.

As a result, the fluctuation of the air path resistance due to the stored item is calculated from the rotational speed of the fan motor or the input current, and the stored amount is estimated, thereby correcting the temperature difference between the temperature detected by the thermistor and the stored item. The temperature of the stored item is always kept in an optimum state, and high freshness can be realized. In addition, the power consumption can be suppressed by preventing the stored item from being “too cold”.

  According to a second invention, in the first invention, the calculation control unit is based on a detection result of the detection unit after a predetermined period has elapsed since the closed state of the heat insulating door was detected by the door opening / closing detection unit. The amount of storage is estimated.

  As a result, in the control to stop the fan motor when the door is opened, the storage amount is estimated after a certain period of time when the operation of the fan motor is stable, except for the transition period immediately after the door is closed and the fan is driven. The estimation accuracy can be increased.

  According to a third invention, in the first or second invention, the operation of the damper is stopped when the detection unit detects a current value or a rotation speed of the fan motor.

  Accordingly, the estimation accuracy of the storage amount can be increased without being affected by the change in the air path resistance due to the opening / closing of the damper.

  According to a fourth aspect of the present invention, in any one of the first to third aspects, the apparatus includes a temperature detection unit that detects a temperature around the cooling fan motor, and the arithmetic processing unit is based on a detection result of the temperature detection unit. Thus, the storage amount of the storage chamber is estimated.

  As a result, it is possible to eliminate the influence on the current and the rotational speed due to temperature fluctuations such as the motor winding resistance value, and to increase the estimation accuracy of the storage amount.

  According to a fifth aspect of the present invention, in any one of the first to fourth aspects of the present invention, the apparatus includes a defrost detection unit that detects defrost of the cooler, and the arithmetic processing unit stores the storage based on a detection result of the defrost detection unit. This is to estimate the storage capacity of the room.

  Thereby, since the influence of the air path resistance change by the frosted state to the said cooler is correct | amended, the estimation precision of storage amount can be improved.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. The present invention is not limited to the embodiment.

(Embodiment 1)
Embodiment 1 of the present invention will be described below with reference to FIGS. FIG. 1 is a side sectional view of a refrigerator according to the first embodiment of the present invention, FIG. 2 is a control block diagram according to the first embodiment, and FIG. 3A is an air volume and static pressure / rotation according to the first embodiment. FIG. 3B is a characteristic diagram of the rotational speed and the storage amount in the first embodiment, FIG. 4 is a control flowchart in the first embodiment, and FIG. FIG. 5B is a characteristic diagram of the rotational speed and the storage amount including the correction factor in the first embodiment, and FIG. 5B is a characteristic diagram of the air volume and the rotational speed including the correction factor in the first embodiment.

  In FIG. 1, reference numeral 1 denotes a heat insulating box body of a refrigerator body, and a heat insulating material is mainly provided in an outer box using a steel plate, an inner box formed of a resin such as ABS, and the space between the outer box and the inner box. With the provided structure, it is insulated from the surroundings.

The refrigerator 1 is thermally partitioned into a plurality of storage rooms, a refrigeration room 2 at the top, a switching room 3 at the bottom of the refrigeration room 2, a freezing room 4 at the bottom of the switching room 3, and the bottom The vegetable compartment 5 is arranged on the front, and the front of each storage compartment is partitioned from the outside air, so that the heat insulating doors 7a to 7d are respectively formed in the front opening of the refrigerator main body.

  A plurality of storage shelves 22 are provided in the refrigerating chamber 2 and are configured to be partially movable up and down.

  The high pressure side components of the refrigeration cycle such as the compressor 8 and a dryer for removing moisture are housed in a machine room formed in the uppermost rear region in the refrigerator compartment 2.

  A cooling chamber for generating cold air is provided on the back surface of the freezer compartment 4, and in the cooling chamber, the cooler 9 and cold air that is cooling means cooled by the cooler are stored in the refrigerator compartment 2, the switching chamber 3, and the freezer compartment 4. A cooling fan 10 for blowing air to the vegetable compartment 5 is disposed. In addition, a defrost heater 11, a drain pan, a drain tube evaporating dish, and the like are configured to defrost frost and ice adhering to the cooler 9 and its surroundings.

  Moreover, in order to detect the temperature around the cooling fan 10 and the cooler 9, the temperature detection means 21 is provided, and plays the following role, for example. One is the role of correcting the influence on the rotational speed or the influence on the output current due to the ambient temperature of the cooling fan 10, and is used to vary the applied voltage according to the ambient temperature. One is a role of detecting the frost formation state on the cooler 9 and is used to detect a decrease in heat exchange property due to frost formation or an increase in air path resistance.

  In the present embodiment, the matter relating to the main part of the invention described below is a type in which a compressor room is disposed by providing a machine room in the rear region of the lowermost storage room of a heat insulation box that has been generally used conventionally. It may be applied to other refrigerators.

  The refrigerator compartment 2 is normally set to 1 ° C. to 5 ° C. at the lower limit for freezing for refrigerated storage, and the lowermost vegetable compartment 5 is set to 2 ° C. to 7 ° C. which is equal to or slightly higher than the refrigerator compartment 2. In addition, the freezer compartment 4 is set in a freezing temperature zone and is usually set at −22 ° C. to −15 ° C. for frozen storage. For example, in order to improve the frozen storage state, −30 ° C. or − It may be set at a low temperature of 25 ° C.

  The switching chamber 3 is refrigerated in addition to refrigerated storage set at 1 ° C to 5 ° C, vegetable storage set at 2 ° C to 7 ° C, and frozen storage usually set at -22 ° C to -15 ° C. The temperature can be switched to a preset temperature range between the temperature range and the freezing temperature range.

  The temperature of each room is controlled by controlling the cooling system, that is, adjusting the motor speed of the compressor 8, adjusting the speed of the cooling fan 10, and adjusting the air volume distribution to each room by opening and closing the damper 12. The damper 12 is a motor that drives a rotary opening and closing part to shield and open the air passage. The opening and closing part is opened halfway to share a breeze in the storage room, and the temperature is finely adjusted by adjusting the opening. It is possible. Normally, if the opening is reduced, the air path resistance increases, and the air volume by the cooling fan 10 decreases.

  In the present embodiment, the switching chamber 3 is a storage room including the temperature range of refrigeration and freezing. However, the refrigeration is performed in the refrigerator room 2 and the vegetable room 5, and the freezing is performed in the freezer room 4 for refrigeration. A storage room specialized for switching only the temperature zone in the middle of freezing may be used. Moreover, the storage room fixed to refrigeration may be sufficient as the demand for frozen foods has increased in recent years, for example, frozen food.

  Moreover, although not shown in figure, the structure which adjoins the switching room and the ice-making room which produces | generates and preserve | saves ice may be sufficient.

  About the refrigerator comprised as mentioned above, the operation | movement * effect | action is demonstrated below.

  The cooling fan 10 has a built-in motor driver and can be driven only by supplying a power supply voltage from the outside. In addition, the number of revolutions per unit time (hereinafter referred to as only the number of revolutions) can be commanded by analog input. In addition, it has a function of outputting the current number of rotations, and has a mechanism for outputting a voltage of a rectangular wave of one pulse every half rotation. However, at the time of detecting the storage amount, the rotation speed is not stabilized by feedback with this function, only a constant voltage is applied, and the rotation speed fluctuates due to disturbance such as wind path resistance.

  At this time, in the cooling fan 10 having the PQ characteristics as shown in FIG. 3A, the rotational speed tends to decrease as the air volume decreases. This is because the static pressure greatly increases due to the decrease in the air volume, and as a result, the load on the cooling fan 10 increases.

  In general, since the load (work volume) of the fan motor is determined by the product of the air volume and the static pressure, the relationship between the air volume and the rotational speed varies depending on the PQ characteristics of the fan motor, and the rotational speed increases as the air volume decreases. It may show a trend.

  Since the air volume of the cooling fan 10 varies depending on the increase / decrease of the air path resistance, that is, the storage capacity of the refrigerator 1, the correlation between the rotation speed and the storage capacity can be obtained as shown in FIG.

  Hereinafter, the storage amount estimation operation in the refrigerator 1 will be described in detail with reference to FIGS.

  In the flowchart of FIG. 4, the door 7 is opened and closed by the door opening / closing detection means 13 to determine whether food can be stored or taken out (step 101), and after a predetermined time is measured by the timer 18 (step 102), the storage amount is detected. To start. This is because the cooling fan 10 is controlled to stop when the door is opened. Therefore, except for the transition period of the cooling fan 10 that is restarted immediately after the door is closed, the storage amount is reduced after the operation is stabilized. This is for detection.

  Next, it is determined whether or not the damper 12 is fully open (step 103). Depending on the opening degree of the damper 12, the air volume decreases as shown in FIG. Therefore, the correction value G is decreased as shown in FIG. 5B (step 104). Since the increase / decrease in the air volume depending on the open / close state of the damper 12 varies depending on the air path configuration, it is necessary to set a correction value for each system.

  Next, the frost formation state on the cooler 9 is determined (step 105). The determination of the frost formation state is performed based on the frost sensor, the temperature detection in the vicinity of the cooler by the temperature detection means 21, or the elapsed time immediately after the defrost by the defrost heater 11. When the amount of frost on the cooler 9 is large, the correction value H is used as shown in FIG. 5B because the air volume is reduced as shown in FIG. Is reduced (step 106).

  Next, the amount of storage is estimated. 3A and 3B, when the air volume is A, the rotation speed of the cooling fan 10 is output as C, and the storage amount is estimated to be E by the storage amount estimation means 16 of the arithmetic control unit 14 (step). 107). The estimated storage amount E is recorded in the storage amount storage means 17 (step 108).

  Finally, the storage amount change is calculated. 3 (a) and 3 (b), when the air volume is B at the previous detection of the storage amount, the rotation speed of the cooling fan 10 is output as D, and the storage amount is estimated by the storage amount estimation means 16 of the arithmetic control unit 14. F is estimated and recorded in the storage amount storage means 17. Since the storage amount detected this time is E, the change in storage amount is the difference between the storage amount F estimated last time and the storage amount E estimated this time (step 109).

  Subsequent cooling control is determined from the storage amount estimated as described above or the storage amount change.

  For example, optimal cooling control according to the situation, such as when the storage amount is extremely small, energy saving operation is performed by controlling the cooling system, or when the storage amount increases rapidly, rapid cooling operation is performed by controlling the cooling system. Select.

  As described above, in the present embodiment, the refrigerating room 2, the switching room 3, the freezing room 4, the vegetable room 5 partitioned by the heat insulating wall and the heat insulating door and storing the stored items, and the cooling for cooling the storage room. Container 9, damper 12 for controlling the amount of cool air to the storage room, heat insulating doors 7a to 7d covering the storage room, door opening / closing detection means 13a to 13d for detecting the opening and closing of the heat insulating doors 7a to d, A cooling fan 10 for supplying cool air to the storage chamber, a rotation speed detection means 15 for detecting the rotation speed of the cooling fan 10, and a calculation control unit 14 for calculating the detection result are provided. By calculating the fluctuation of the fan motor from the rotation speed of the fan motor and estimating the storage amount, it is possible to detect the load fluctuation in the storage due to the storage amount change faster than the temperature detection temperature of the thermistor, thereby cooling quickly. The ability to properly control Becomes ability, the temperature of the stored item is kept optimal, it is possible to realize a high freshness, by preventing "cold too" of stored items, it is possible to suppress the power consumption.

(Embodiment 2)
The second embodiment of the present invention will be described below with reference to FIGS. FIG. 6 is a control block diagram in the second embodiment, FIG. 7A is a characteristic diagram of air volume and static pressure / input current in the second embodiment, and FIG. 7B is a second embodiment. FIG. 8 is a control flowchart in the second embodiment of the present invention, and FIG. 9A is a characteristic diagram of the air volume and the input current including correction factors in the second embodiment. FIG. 9B is a characteristic diagram of the input current and the storage amount including the correction factor in the second embodiment. The same parts as those of the first embodiment are denoted by the same reference numerals and different parts will be described.

  About the refrigerator comprised as mentioned above, the operation | movement * effect | action is demonstrated below.

  The cooling fan 10 has a built-in motor driver and can be driven only by supplying a power supply voltage from the outside. In addition, the number of revolutions per unit time (hereinafter referred to as only the number of revolutions) can be commanded by analog input. In addition, it has a function of outputting the current number of rotations, and has a mechanism for outputting a voltage of a rectangular wave of one pulse every half rotation. In the present embodiment, when the storage amount is detected, the rotational speed is made constant by feedback with this function, and the input current to the fan is likely to fluctuate due to disturbance such as air path resistance.

  At this time, in the cooling fan 10 having the PQ characteristic as shown in FIG. 7A, the input current tends to increase as the air volume decreases. This is because the static pressure greatly increases due to the decrease in the air volume, and as a result, the load on the cooling fan 10 increases.

  In general, since the load (work volume) of the fan motor is obtained by the product of the air volume and the static pressure, the relationship between the air volume and the input current varies depending on the PQ characteristics of the fan motor, and the input current also decreases as the air volume decreases. It may show a trend.

  Since the air volume of the cooling fan 10 varies depending on the increase / decrease of the airflow resistance, that is, the storage capacity of the refrigerator 1, the correlation between the input current and the storage capacity can be obtained as shown in FIG.

  Hereinafter, the storage amount estimation operation in the refrigerator compartment 2 will be described in detail with reference to FIGS.

  In the flowchart of FIG. 8, the door 7 is opened and closed by the door open / close detection means 13 to determine whether food can be stored or taken out (step 201), and a predetermined time is counted by the timer 18 (step 202). To start. This is because the cooling fan 10 is controlled to stop when the door is opened. Therefore, except for the transition period of the cooling fan 10 that is restarted immediately after the door is closed, the storage amount is reduced after the operation is stabilized. This is for detection.

  Next, it is determined whether or not the damper 12 is fully opened (step 203). Depending on the opening degree of the damper 12, the input current increases as shown in FIG. Therefore, the correction value R is reduced as shown in FIG. 9B (step 204). Since the increase / decrease in the air volume depending on the open / close state of the damper 12 varies depending on the air path configuration, it is necessary to set a correction value for each system.

  Next, the frost formation state on the cooler 9 is determined (step 205). The determination of the frost formation state is performed based on the frost sensor, the temperature detection in the vicinity of the cooler by the temperature detection means 21, or the elapsed time immediately after the defrost by the defrost heater 11. When the amount of frost formation on the cooler 9 is large, the input current increases as shown in FIG. 9 (a) even if the storage amount is the same, so that the storage amount is determined to be large. Therefore, a correction value as shown in FIG. S is decreased (step 206).

  Next, the amount of storage is estimated. The input current of the cooling fan 10 is performed by a current detector 20 such as a current transformer or a shunt method. Generally, since the input current to the motor is not a direct current, it is handled with a peak value, an effective value, or a value smoothed by a capacitor.

  7A and 7B, when the air volume is J, the input current of the cooling fan 10 is L, and the storage amount is estimated to be N by the storage amount estimation means 16 of the arithmetic control unit 14 (step 207). . The estimated storage amount N is recorded in the storage amount storage means 17 (step 208).

  Finally, the storage amount change is calculated. 7 (a) and 7 (b), when the previous storage amount was detected, when the air volume was K, the input current of the cooling fan 10 was M, and the storage amount was estimated to be O by the storage amount estimation means 16 of the arithmetic control unit 14. It is estimated and recorded in the storage amount storage means 17. Since the storage amount detected this time is N, the storage amount change is the difference between the storage amount O estimated last time and the storage amount N estimated this time (step 209).

  Subsequent cooling control is determined from the storage amount estimated as described above or the storage amount change.

  As described above, in the present embodiment, the refrigerating room 2, the switching room 3, the freezing room 4, the vegetable room 5 partitioned by the heat insulating wall and the heat insulating door and storing the stored items, and the cooling for cooling the storage room. Container 9, damper 12 for controlling the amount of cool air to the storage room, heat insulating doors 7a to 7d covering the storage room, door opening / closing detection means 13a to 13d for detecting the opening and closing of the heat insulating doors 7a to d, A cooling fan 10 that supplies cool air to the storage chamber, a current detection means 20 that detects an input current value of the cooling fan 10, and an arithmetic control unit 14 that performs arithmetic processing on the detection result are provided. By calculating the fan fluctuation from the fan motor input current and estimating the storage amount, it is possible to detect the load fluctuation in the storage due to the storage amount change faster than the temperature detection temperature of the thermistor. Appropriate control of capacity Becomes possible, the temperature of the stored item is kept optimal, it is possible to realize a high freshness, by preventing "cold too" of stored items, it is possible to suppress the power consumption.

(Embodiment 3)
The third embodiment of the present invention will be described below with reference to FIGS. FIG. 10 is a control block diagram according to the third embodiment, FIG. 11A is a characteristic diagram of air volume and static pressure / rotation speed according to the third embodiment, and FIG. 11B is a third embodiment. FIG. 12 is a control flowchart in the third embodiment. The same parts as those in the first or second embodiment are denoted by the same reference numerals and different parts will be described.

  The refrigerator according to the third embodiment configured as described above is characterized in that there is no correction step (steps 103 to 106) according to the first embodiment, and hereinafter, means for estimating a change in storage amount The explanation will be focused on.

  The configuration of the cooling fan 10 is the same as that of the first embodiment, and detailed description thereof is omitted.

  In the flowchart of FIG. 12, in the third embodiment, the storage amount is estimated by the number of rotations of the cooling fan 10 every predetermined time even when the door 7 is not opened or closed by the time measurement by the timer 18 (step 301). The storage amount estimated here is recorded in the storage amount storage means 17 (step 303), and conditions that may cause an error in storage amount detection, such as the operating state of the compressor 8 at the time of detection and the open / close state of the damper 12, are detected. It records in the condition storage means 23 (step 304). At this time, from FIGS. 11A and 11B, when the air volume is U, the number of rotations of the cooling fan 10 is output as W, and the storage amount is estimated as Y by the storage amount estimation means 16 of the arithmetic control unit 14. ing.

  As described above, the storage amount immediately before food storage is always managed.

  Thereafter, using this data as a reference, the yield change is estimated by comparing with the storage amount detected after food storage.

  When the door 7 is opened and closed by the door opening / closing detection means 13 and the possibility of food storage or removal is determined (step 305), the storage amount detection is started after a predetermined time is counted by the timer 18 (step 306). This is because the cooling fan 10 is controlled to stop when the door is opened. Therefore, except for the transition period of the cooling fan 10 that is restarted immediately after the door is closed, the storage amount is reduced after the operation is stabilized. This is for detection.

  Next, before the storage amount is estimated, the operation state of the compressor 8 and the opening / closing state of the damper 12 recorded in the detection condition storage means 23 in step 304 are read, and the operation of the refrigerator is adjusted to the same condition (step 307). As a result, changes in airway resistance caused by factors other than food storage are equivalent to those at the time of storage amount detection immediately before food is added. In addition, since the time interval for detecting the storage amount before and after food storage is relatively short, the frosting state on the cooler 9 is almost the same as before food storage.

  That is, an error factor is eliminated in comparing the storage amounts before and after food storage, and the correction process as in the first and second embodiments is not necessary.

  Next, the storage amount is estimated. 11A and 11B, when the air volume is T, the rotation speed of the cooling fan 10 is output as V, and the storage amount is estimated to be X by the storage amount estimation means 16 of the arithmetic control unit 14 (step). 308). The estimated storage amount X is recorded in the storage amount storage means 17 (step 309).

  Finally, the storage amount change is calculated. Since the storage amount immediately before food storage is recorded as Y, and the storage amount detected after storage is X, the storage amount change is the difference between X and Y (step 310).

  Subsequent cooling control is determined from the storage amount change estimated as described above.

  For example, when the storage amount increases rapidly, the optimum cooling control corresponding to the situation is selected, for example, a rapid cooling operation is performed by the control of the cooling system.

  As described above, in the present embodiment, the refrigerating room 2, the switching room 3, the freezing room 4, the vegetable room 5 partitioned by the heat insulating wall and the heat insulating door and storing the stored items, and the cooling for cooling the storage room. Container 9, damper 12 for controlling the amount of cool air to the storage room, heat insulating doors 7 a to d covering the storage room, door open / close detection means 13 a to d for detecting opening and closing of the heat insulating doors 7 a to d, A cooling fan 10 for supplying cool air to the storage chamber, a rotation speed detection means 15 for detecting the rotation speed of the cooling fan 10, and a calculation control unit 14 for calculating the detection result are provided. Is calculated from the rotation speed of the fan motor, and the change in the storage amount is estimated, whereby the optimum temperature management in accordance with the storage of the food is possible, and high freshness can be realized.

  Although the storage amount change detection using the rotation speed of the cooling fan 10 has been described in the third embodiment, it is also possible to detect the storage amount change by the input current as in the second embodiment.

  In the first to third embodiments, it is possible to detect the storage amount of the storage chamber connected to the cooling fan 10 through the air path.

  Furthermore, in those equipped with dampers for each of the plurality of storage chambers, when estimating the storage amount, only the damper of the target storage chamber is opened, and the other is calculated in the closed state, It is also possible to estimate the individual storage amount of each storage room.

  In Embodiments 1 to 3, the change in the storage amount before and after the door opening / closing is calculated and controlled. However, the storage amount in FIG. 3 (b) and FIG. 7 (b) and the rotational speed of the fan motor or Of course, it is possible to predict the absolute storage amount at the time of estimation using the correlation data with the current value.

  The refrigerator according to the present invention can be implemented and applied to control for switching the operation mode to a power saving operation or the like by providing a storage amount detection function in a home or business refrigerator.

1 Refrigerator (insulated box)
2 Refrigeration room 3 Switching room 4 Freezing room 5 Vegetable room 6a, 6b, 6c Partition wall 7a, 7b, 7c, 7d Thermal insulation door 8 Compressor 9 Cooler 10 Cooling fan 11 Defrost heater 12 Damper 13, 13a, 13b, 13c 13d Door opening / closing detection means 14 Calculation control section 15 Rotational speed detection means 16 Storage amount estimation means 17 Storage amount storage means 18 Timer 19 Correction means 20 Current detection means 21 Temperature detection means 22 Storage shelf 23 Detection condition storage means

Claims (5)

A storage room that is partitioned by a heat insulating wall and a heat insulating door and stores storage items, a cooler for cooling the storage room, a damper that controls the amount of cool air to the storage room, and a heat insulating door that covers the storage room A door opening / closing detecting means for detecting opening / closing of the heat insulating door, a cooling fan for supplying cool air to the storage chamber, a fan motor for driving the cooling fan, and a rotational speed or a current value of the fan motor. A detection unit; and a calculation control unit that performs calculation processing on a detection result of the detection unit, wherein the calculation control unit is based on the detection result of the door opening / closing detection unit and the detection result of the detection unit. A refrigerator characterized by estimating the amount of storage. The calculation control unit estimates a storage amount based on a detection result of the detection unit after a predetermined period has elapsed since the closed state of the heat insulating door was detected by the door opening / closing detection unit. Item 10. The refrigerator according to Item 1. The refrigerator according to claim 1 or 2, wherein when the detection unit detects a current value or a rotation speed of the fan motor, the operation of the damper is stopped. The temperature control means which detects the temperature around the said cooling fan is provided, and the said calculation control part estimates the storage amount of the said storage chamber based on the detection result of the said temperature detection means. The refrigerator as described in any one of. The defrost detection means for detecting the defrost of the cooler is provided, and the calculation control unit estimates the storage amount of the storage chamber based on the detection result of the defrost detection means. A refrigerator according to claim 1.