JP2018013299A - refrigerator - Google Patents

Abstract

PROBLEM TO BE SOLVED: To promote the production of nutrients by photosynthesis of vegetables and the like during storage, suppress wasteful consumption and excess transpiration of sugar obtained by photosynthesis, and store fruits and vegetables in a storage room with good freshness and high quality. Provide a nice refrigerator. SOLUTION: A refrigerator is provided with a storage chamber for storing food, a cooling means for cooling the inside of the storage chamber, and a light emitting unit capable of irradiating the inside of the storage chamber with visible light. The light emitting unit carries out the first step of irradiating the light with the first radiant intensity for the first duration and the second step of irradiating the light with the second radiant intensity lower than the first radiant intensity. Implement for the second duration. The cooling means is such that the light emitting unit brings the inside of the storage chamber to the first temperature while the light emitting unit is performing the first step, and the light emitting unit keeps the inside of the storage chamber lower than the first temperature while performing the second step. To the temperature of. [Selection diagram] Fig. 6

Description

  The present invention relates to a refrigerator.

  In a conventional refrigerator, a single light source or a plurality of light sources that are arranged in a refrigerator and irradiate predetermined ultraviolet rays directly or through a translucent plate mainly on a specific storage container or a stored item stored in a specific location, Or the control apparatus provided in the refrigerator main body which light-extinguishes a several light source at intervals, and what turned off time longer than the time to light is known (for example, refer patent document 1).

  In addition, the refrigerator body is provided in a vegetable compartment consisting of one compartment partitioned into a plurality of compartments, a vegetable compartment case made of a non-light transmissive material provided in the vegetable compartment, and a part of the bottom of the vegetable compartment case. An opening, a lid made of a light-transmitting material installed so as to close the opening, and a light irradiation device provided on the floor of the vegetable room and having a light source for irradiating light. In the state where the vegetable compartment case is housed in the vegetable compartment, the vegetable compartment case is irradiated with light through the lid from below the vegetable compartment case, and includes a plurality of semiconductor light emitting elements as a light source, A refrigerator in which a semiconductor light emitting element is turned on or off at preset times is also conventionally known (see, for example, Patent Document 2).

JP 2006-329614 A JP 2007-046840 A

  However, in the conventional refrigerators as shown in these Patent Documents 1 and 2, the temperature in the vegetable compartment when the light source for irradiating light in the vegetable compartment is turned on and off is completely different. Not considered. For this reason, when the light source is turned on to promote photosynthesis of vegetables in the vegetable compartment, the temperature in the vegetable compartment is not necessarily appropriate for photosynthesis, and the effect of promoting photosynthesis may be diminished. Similarly, the temperature environment in the vegetable room when the light source is turned off may not be appropriate for suppressing moisture transpiration from the vegetable.

  The present invention has been made to solve such a problem, and can promote the production of nutrients by photosynthesis of preserved vegetables and the like (fruits and vegetables), and wasteful consumption of sugar obtained by photosynthesis. In addition, it is possible to obtain a refrigerator that can suppress excessive transpiration and can preserve fruits and vegetables in the storage room with high freshness and high quality.

  The refrigerator according to the present invention includes a storage room for storing food, a cooling means for cooling the inside of the storage room, and a light emitting unit capable of irradiating visible light inside the storage room, and the light emitting unit Performs a first step of irradiating light with a first radiation intensity for a first duration and a second step of irradiating light with a second radiation intensity lower than the first radiation intensity. The cooling means is configured to set the interior of the storage chamber to a first temperature while the light emitting unit is performing the first step, and the light emitting unit is performing the second step. The inside of the storage chamber is configured to be a second temperature lower than the first temperature.

  In the refrigerator according to the present invention, it is possible to promote the generation of nutrients by photosynthesis of preserved vegetables and the like (fruits and vegetables), and to suppress wasteful consumption of sugar obtained by photosynthesis and excessive transpiration. The fruit and vegetables in the storage room can be stored with high freshness and high quality.

It is a front view of the refrigerator which concerns on Embodiment 1 of this invention. It is a longitudinal cross-sectional view of the refrigerator which concerns on Embodiment 1 of this invention. It is the figure which expanded and showed the vegetable compartment part of FIG. It is a block diagram which shows the structure of the control system of the refrigerator which concerns on Embodiment 1 of this invention. It is a block diagram which shows the structure of the control apparatus of FIG. It is a time chart of light irradiation control and temperature control of the refrigerator which concerns on Embodiment 1 of this invention. It is a flowchart which shows the flow of light irradiation control and temperature control of the refrigerator which concerns on Embodiment 1 of this invention.

  DESCRIPTION OF EMBODIMENTS Embodiments of the present invention will be described with reference to the accompanying drawings. In the drawings, the same or corresponding parts are denoted by the same reference numerals, and overlapping descriptions are simplified or omitted as appropriate. The present invention is not limited to the following embodiments, and various modifications can be made without departing from the spirit of the present invention.

Embodiment 1 FIG.
1 to 6 relate to Embodiment 1 of the present invention. FIG. 1 is a front view of the refrigerator, FIG. 2 is a longitudinal sectional view of the refrigerator, and FIG. 3 is an enlarged view of the vegetable compartment portion of FIG. 4 is a block diagram showing the configuration of the control system of the refrigerator, FIG. 5 is a block diagram showing the configuration of the control device of FIG. 4, FIG. 6 is a time chart of light irradiation control and temperature control of the refrigerator, and FIG. It is a flowchart which shows the flow of light irradiation control and temperature control of a refrigerator.

  In each drawing, the dimensional relationship and shape of each component may be different from the actual one. Moreover, the positional relationship (for example, up-and-down relationship etc.) between each structural member is a thing when installing the refrigerator in a usable state in principle.

(Composition of refrigerator)
The refrigerator 1 according to Embodiment 1 of the present invention has a heat insulating box 90 as shown in FIG. The heat insulation box 90 has a front surface (front) opened and a storage space formed therein. The heat insulation box 90 has an outer box, an inner box, and a heat insulating material. The outer box is made of steel. The inner box is made of resin. The inner box is arranged inside the outer box. The heat insulating material is, for example, urethane foam and is filled in a space between the outer box and the inner box. The storage space formed inside the heat insulation box 90 is partitioned into a plurality of storage chambers for storing and storing food by one or a plurality of partition members.

  As shown in FIGS. 1 and 2, the refrigerator 1 includes, for example, a refrigerator room 100, a switching room 200, an ice making room 300, a freezer room 400, and a vegetable room 500 as a plurality of storage rooms. These storage chambers are arranged in a four-stage configuration in the vertical direction in the heat insulating box 90.

  The refrigerator compartment 100 is disposed on the uppermost stage of the heat insulation box 90. The switching chamber 200 is disposed on one side of the left and right below the refrigerator compartment 100. The cold insulation temperature zone of the switching chamber 200 can be switched by selecting one of a plurality of temperature zones. The plurality of temperature zones that can be selected as the cool temperature zone of the switching chamber 200 are, for example, a freezing temperature zone (for example, about −18 ° C.), a refrigeration temperature zone (for example, about 3 ° C.), a chilled temperature zone (for example, about 0 ° C.), and the like. Soft freezing temperature range (for example, about -7 ° C.). The ice making chamber 300 is disposed adjacent to the side of the switching chamber 200 in parallel with the switching chamber 200, that is, on the left and right other sides below the refrigerator compartment 100.

  The freezing room 400 is disposed below the switching room 200 and the ice making room 300. The freezer compartment 400 is mainly used when the object to be stored is stored frozen for a relatively long period of time. The vegetable room 500 is arranged at the lowermost stage below the freezer room 400. The vegetable room 500 is mainly for storing vegetables and large-sized plastic bottles having a large capacity (for example, 2 L).

  The opening formed in the front surface of the refrigerator compartment 100 is provided with a rotary refrigerator compartment door 7 that opens and closes the opening. Here, the refrigerator compartment door 7 is a double door type (double door type), and is constituted by a right door 7a and a left door 7b. An operation panel 6 is provided on the outer surface of the refrigerator compartment door 7 (for example, the left door 7 b) on the front surface of the refrigerator 1. The operation panel 6 includes an operation unit 6a and a display unit 6b. The operation unit 6a is an operation switch for setting the cold temperature of each storage room and the operation mode (such as the thawing mode) of the refrigerator 1. The display unit 6b is a liquid crystal display that displays various types of information such as the temperature of each storage room. The operation panel 6 may include a touch panel that serves as both the operation unit 6a and the display unit 6b.

  Each storage room (the switching room 200, the ice making room 300, the freezer room 400, and the vegetable room 500) other than the refrigerator room 100 is opened and closed by a drawer door. These drawer-type doors slide in the depth direction (front-rear direction) of the refrigerator 1 by sliding a frame fixed to the door with respect to rails formed horizontally on the left and right inner wall surfaces of each storage room. It can be opened and closed.

  Further, inside the switching chamber 200 and the inside of the freezer compartment 400, a switching chamber storage case 201 and a freezer compartment storage case 401 that can store foods and the like are stored in a freely retractable manner. Similarly, in the vegetable compartment 500, an upper storage case 11 and a lower storage case 10 that can store food and the like are stored in a freely retractable manner.

(Cooling mechanism)
The refrigerator 1 includes a refrigeration cycle circuit that cools the air supplied to each storage room. The refrigeration cycle circuit includes a compressor 2, a condenser (not shown), a throttling device (not shown), a cooler 3, and the like. The compressor 2 compresses and discharges the refrigerant in the refrigeration cycle circuit. The condenser condenses the refrigerant discharged from the compressor 2. The expansion device expands the refrigerant that has flowed out of the condenser. The cooler 3 cools the air supplied to each storage chamber by the refrigerant expanded by the expansion device. The compressor 2 is arrange | positioned at the lower part of the back side of the refrigerator 1, for example.

  The refrigerator 1 is formed with an air passage 5 for supplying the air cooled by the refrigeration cycle circuit to each storage chamber. The air passage 5 is mainly disposed on the back side in the refrigerator 1. The cooler 3 of the refrigeration cycle circuit is installed in the air path 5. Further, a blower fan 4 for sending the air cooled by the cooler 3 to each storage chamber is also installed in the air passage 5.

  When the blower fan 4 operates, the air (cold air) cooled by the cooler 3 is sent to the freezing room 400, the switching room 200, the ice making room 300, and the refrigerating room 100 through the air path 5, and these storage rooms are passed through. Cooling. The vegetable room 500 is cooled by introducing the return cold air from the refrigerating room 100 into the vegetable room 500 through the return air passage for the refrigerating room. The cold air that has cooled the vegetable compartment 500 is returned to the air passage 5 with the cooler 3 through the vegetable compartment return air passage (these return air passages are not shown). And it cools again by the cooler 3, and cold air is circulated through the refrigerator 1.

  A damper (not shown) is provided at a midway point from the air passage 5 to each storage chamber. Each damper opens and closes a portion of the air passage 5 that leads to each storage chamber. By changing the open / close state of the damper, the amount of cool air supplied to each storage chamber can be adjusted. Further, the temperature of the cold air can be adjusted to control the operation of the compressor 2.

  The refrigeration cycle circuit including the compressor 2 and the cooler 3, the blower fan 4, the air path 5, and the damper provided as described above constitute a cooling unit that cools the inside of the storage chamber.

  A control device 8 is accommodated in the upper portion of the refrigerator 1 on the back side, for example. The control device 8 is provided with a control circuit and the like for performing various controls necessary for the operation of the refrigerator 1. As a control circuit with which the control apparatus 8 is provided, for example, a circuit for controlling the operation of the compressor 2 and the blower fan 4 and the opening degree of the damper based on the temperature in each storage chamber and information input to the operation panel 6 or the like. Can be mentioned. That is, the control device 8 controls the operation of the refrigerator 1 by controlling the cooling means and the like described above. The temperature in each storage chamber can be detected by a thermistor or the like installed in each storage chamber.

(Composition of vegetable room)
FIG. 3 is a cross-sectional view of the vegetable compartment 500 portion included in the refrigerator 1. The vegetable room 500 is a storage room for storing food, particularly vegetables. The lower storage case 10 is supported by a frame (not shown) of the vegetable compartment door 9. An upper storage case 11 is placed on the upper side of the lower storage case 10. When the vegetable compartment door 9 is pulled forward, the lower storage case 10 and the upper storage case 11 are integrated with the vegetable compartment door 9 and pulled forward. When only the upper storage case 11 is slid rearward with the vegetable compartment door 9 pulled out, only the lower storage case 10 is pulled out. In a state where only the lower storage case 10 is pulled out, food can be taken in and out of the lower storage case 10.

  Inside the vegetable compartment 500, a door open / close detection switch 12, a thermistor 13, and a light emitting unit 14 are provided. The door open / close detection switch 12 is for detecting the open / closed state of the vegetable compartment door 9. The door open / close detection switch 12 is provided at a position facing the vegetable compartment door 9 at the edge of the front opening of the vegetable compartment 500.

  A thermistor 13 and a light emitting unit 14 are attached to the back surface of the vegetable compartment 500. The thermistor 13 detects the temperature in the vegetable compartment 500. The light emission part 14 can irradiate the inside of the vegetable compartment 500 which is a storage room with visible light. Here, an opening 15 is formed in a portion facing the light emitting unit 14 on the back surface of the lower storage case 10. The light emitting unit 14 can irradiate the inside of the lower storage case 10 with visible light through the opening 15. Note that a material having a property of transmitting visible light emitted from the light emitting unit 14 may be used in at least a portion corresponding to the opening 15 of the lower storage case 10.

(Configuration of light emitting part)
As described above, the light emitting unit 14 can irradiate visible light. Here, it is assumed that the light emitting unit 14 is, for example, a white LED including three types of light emitting elements. The three types of light emitting elements included in the light emitting unit 14 emit, for example, three primary colors of light, that is, red, green, and blue light, respectively. Specifically, the light emitting element that emits red light emits light having a center wavelength of 600 nm to 780 nm, for example. Specifically, the light emitting element that emits green light emits light having a center wavelength of 500 nm to 550 nm, for example. Specifically, the light emitting element that emits blue light emits light having a center wavelength of not less than 430 nm and not more than 500 nm, for example. The light emitting unit 14 is configured to emit white light when all of these three primary color light emitting elements are simultaneously lit at the rated output. Here, the three primary color light emitting elements included in the light emitting unit 14 are , Each can be turned on and off independently.

(Refrigerator control system)
FIG. 4 is a block diagram showing a functional configuration of the control system of the refrigerator 1. In FIG. 4, a portion related particularly to the control of the vegetable compartment 500 is shown. The control device 8 includes, for example, a microcomputer, and includes a CPU 8a and a memory 8b. The control device 8 controls the refrigerator 1 by executing a preset process when the CPU 8a executes a program stored in the memory 8b.

  A detection signal of the temperature inside the vegetable compartment 500 is input from the thermistor 13 to the control device 8. Further, an operation signal from the operation unit 6 a of the operation panel 6 is also input to the control device 8. Further, a detection signal from the door open / close detection switch 12 is also input to the control device 8.

  Based on the input signal, the control device 8 executes a process for controlling the operations of the compressor 2 and the blower fan 4 so that the inside of the vegetable compartment 500 is maintained at the set temperature. The control device 8 also outputs a control signal to the light emitting unit 14 to control the light emitting operation of the light emitting unit 14. Further, the control device 8 outputs a display signal to the display unit 6b of the operation panel 6 to control the display operation of the display unit 6b.

(Configuration of control device)
Next, the configuration of the control device 8 will be described with reference to FIG. As shown in FIG. 5, the control device 8 includes a light emission control unit 21, a temperature control unit 22, a storage unit 23, a time measuring unit 24, and a season specifying unit 25. The light emission control unit 21 is particularly responsible for the light emission operation control of the light emitting unit 14 among various controls by the control device 8 described above. As described above, the light emitting unit 14 includes three primary color light emitting elements. The light emission control unit 21 can individually control lighting and extinction of the three primary color light emitting elements included in the light emitting unit 14 for each element.

  Among the various controls by the control device 8 described above, the temperature control unit 22 particularly controls the cooling means such as the compressor 2 and the blower fan 4. The temperature control unit 22 controls the cooling means so that the temperature inside the vegetable room 500 serving as a storage room becomes a set temperature.

  Various types of information such as parameters necessary for control by the light emission control unit 21 and the temperature control unit 22 are stored in the storage unit 23 in advance. The time measuring unit 24 measures an elapsed time from a specific time when the light emission control unit 21 and the temperature control unit 22 perform control. The timer unit 24 may include a clock function that measures the current time and a calendar function that specifies the current date.

  The season specifying unit 25 specifies the current season. The season specifying unit 25 specifies the current season based on the current month and date specified by the time measuring unit 24, for example. In addition, for example, the current season may be specified based on the detection result of an outside temperature sensor (not shown) that detects the temperature outside the refrigerator 1. Alternatively, the season specifying unit 25 may allow the user to input the current season by operating the operation unit 6a of the operation panel 6. At this time, the season specifying unit 25 may also use information on the country in which the refrigerator 1 is installed, information on the latitude and longitude of the installation location, and the like to specify a season suitable for the location to be used. . It is conceivable that information such as country, latitude, and longitude can be input from the operation panel 6 by the user.

(Light irradiation and temperature control)
Next, the light emission operation control of the light emitting unit 14 and the temperature control in the vegetable compartment 500 (operation control of the cooling means) by the control device 8 will be described with reference to FIG. The light emission control unit 21 performs a first process in which light is emitted from the light emitting unit 14 with the first radiation intensity. That is, under the control of the light emission control unit 21, the light emitting unit 14 performs the first step of irradiating light with the first radiation intensity. Moreover, the light emission control part 21 performs the 2nd process irradiated with light with the 2nd radiation intensity from the light emission part 14. FIG. That is, under the control of the light emission control unit 21, the light emitting unit 14 performs the second step of irradiating light with the second radiation intensity.

  The second radiant intensity in the second step is lower than the first radiant intensity in the first step. Here, for example, the first radiant intensity is the radiant intensity in a state where the light emitting unit 14 is lit at the rated value, and the second radiant intensity is the radiant intensity in a state where no light is emitted from the light emitting unit 14, that is, “0”. And

  Further, the first step is performed only for the first duration. The second step is performed for the second duration. Specific values of the first duration and the second duration are stored in the storage unit 23 in advance. For example, each of the first duration time and the second duration time is 5 hours or more, preferably 5 hours or more and 15 hours or less.

  In addition, the light emission control unit 21 performs control so that the light emitting unit 14 repeatedly performs the first process and the second process. That is, under the control of the light emission control unit 21, the light emitting unit 14 alternately performs the first process and the second process. At this time, it is desirable that the sum of the first duration and the second duration be 24 hours or less.

  When the light emission control unit 21 controls the light emission unit 14 to perform the first step, the temperature control unit 22 controls the cooling unit so that the inside of the vegetable compartment 500 becomes the first temperature. That is, under the control of the temperature control unit 22, the cooling unit brings the inside of the vegetable compartment 500 to the first temperature while the light emitting unit 14 is performing the first step. Moreover, when the light emission control part 21 is controlling so that the light emission part 14 may implement a 2nd process, the temperature control part 22 controls a cooling means so that the inside of the vegetable compartment 500 may become 2nd temperature. To do. That is, under the control of the temperature control unit 22, the cooling unit brings the inside of the vegetable compartment 500 to the second temperature while the light emitting unit 14 is performing the second step.

  The second temperature is a temperature lower than the first temperature. Specific values of the first temperature and the second temperature are stored in the storage unit 23 in advance. The first temperature and the second temperature are temperatures from the freezing point of the vegetable to a cold dark place level, specifically, for example, a range of -1 ° C to 15 ° C. For example, the first temperature is in the range of 5 ° C. to 15 ° C., the second temperature is in the range of −1 ° C. to 10 ° C., and the second temperature is lower than the first temperature. Set to FIG. 6 shows a case where the first temperature is 6 ° C. and the second temperature is 0 ° C.

  As described above, in the first step, the light emitting unit 14 emits light with a relatively high first radiation intensity, and the temperature inside the vegetable compartment 500 is relatively high by the cooling means. To be. In the second step, the light emitting unit 14 emits light with a relatively low second radiation intensity, and the temperature inside the vegetable compartment 500 is set to a relatively low second temperature by the cooling means. . This first step simulates the daytime condition in the natural environment, and is hereinafter referred to as “daytime mode”. On the other hand, the second step simulates the night state in the natural environment, and is hereinafter referred to as “night mode”.

  Here, the first duration of the first step and the second duration of the second step may be set according to the season. That is, in this case, the storage unit 23 stores in advance the values of the first duration and the second duration for each season. And the light emission control part 21 acquires the value of the 1st continuation time corresponding to the present season specified by the season specific | specification part 25, and the 2nd duration from the memory | storage part 23, This acquired 1st continuation The light emitting unit 14 is caused to perform the first step and the second step according to the value of the time and the second duration time. At this time, if information on the country or latitude in which the refrigerator 1 is installed is available, the first duration time and the second duration time are further matched to the daytime and night time according to the latitude height. May be set.

  Further, the first temperature during the first step and the second temperature during the second step may also be set according to the season. That is, in this case, the storage unit 23 stores in advance the first temperature value and the second temperature value for each season. And the temperature control part 22 acquires the value of the 1st temperature and 2nd temperature corresponding to the present season specified by the season specific | specification part 25 from the memory | storage part 23, and this acquired 1st temperature and 1st The cooling means is controlled using the temperature value of 2 as the target value of the internal temperature of the vegetable compartment 500 during the first step and the second step. At this time, if information on the country or latitude and longitude in which the refrigerator 1 is installed is available, the values of the first temperature and the second temperature are further set in accordance with the climate according to the country or latitude and longitude. It may be set.

  A series of flows relating to the control of the internal temperature of the light emitting unit 14 and the vegetable compartment 500 included in the refrigerator 1 configured as described above will be described with reference to the flowchart of FIG. First, when the power of the refrigerator 1 is turned on in step S1, in step S2, the control device 8 determines whether or not the current time measured by the time measuring unit 24 belongs to the daytime mode time zone.

  At this time, for example, it is set in advance that 6 to 18:00 is set as the daytime mode time zone, and the other (18 to 6 o'clock) is set as the night mode time zone. The daytime mode time zone and the night mode time zone may be changed by the season specifying unit 25 according to the season. That is, it may be set such that the daytime mode time zone is the longest around the summer solstice and the daytime mode time zone is the shortest around the winter solstice.

  In step S2, if the current time belongs to the daytime mode time zone, the process proceeds to step S3. In step S <b> 3, the light emission control unit 21 turns on the light emitting unit 14. That is, the light emitting unit 14 emits light with the first radiation intensity. In subsequent step S4, the temperature control unit 22 controls the cooling means so that the set temperature of the vegetable compartment 500 is the first temperature and the internal temperature of the vegetable compartment 500 is the first temperature.

  After step S4, the process proceeds to step S5. In step S5, the timer unit 24 resets the value of the timer that measures the elapsed time to 0, and starts measuring the elapsed time using the timer. In subsequent step S6, the control device 8 checks whether or not the elapsed time of the timer of the time measuring unit 24 has reached the first duration time. If the elapsed time of the timer has not reached the first duration, the process returns to step S3.

  On the other hand, when the elapsed time of the timer becomes the first duration in step S6, the process proceeds to step S7. In step S2, if the current time does not belong to the daytime mode time zone, the process proceeds directly from step S2 to step S7 without going through steps S3 to S6. The above steps S3 to S6 are the first step, that is, the daytime mode.

  In step S7, the light emission control unit 21 turns off the light emitting unit 14. That is, the light emitting unit 14 emits light with the second radiation intensity. In subsequent step S8, the temperature control unit 22 controls the cooling means so that the set temperature of the vegetable compartment 500 is set to the second temperature, and the internal temperature of the vegetable compartment 500 becomes the second temperature.

  After step S8, the process proceeds to step S9. In step S9, the timer unit 24 resets the value of the timer that measures the elapsed time to 0, and starts measuring the elapsed time using the timer. In subsequent step S10, the control device 8 confirms whether or not the elapsed time of the timer of the timer unit 24 has reached the second duration. If the elapsed time of the timer has not reached the second duration, the process returns to step S7.

  On the other hand, when the elapsed time of the timer becomes the first duration in step S10, the process returns to step S3 and the above steps are repeatedly executed. The above steps S7 to S10 are the second step, that is, the night mode.

(Action by light irradiation and temperature control)
Next, the effect | action anticipated by the light irradiation of the above light emission parts 14 and the temperature control of the vegetable compartment 500 is demonstrated. First, the plant photosynthesis reaction will be described. The photosynthetic reaction can be expressed by the following formula (1).

6CO ₂ + 12H ₂ O + 688 kcal → C ₆ H ₁₂ O ₆ + 6H ₂ O + 6O ₂ (1)

In the formula (1), CO ₂ : carbon dioxide, H ₂ O: water, 688 kcal: light energy, C ₆ H ₁₂ O ₆ : glucose.

  By the photosynthesis reaction of the formula (1), the plant generates oxygen and sugar from carbon dioxide in the atmosphere and water of the plant using light energy. This reaction is divided into two stages. The first step is to break down water into hydrogen and oxygen using light energy absorbed by pigments such as chlorophyll contained in leaves, and store chemical energy through the action of enzyme proteins. The second step synthesizes glucose using electrons, hydrogen ions and carbon dioxide in the atmosphere. Vegetables with increased glucose are better stored and produce vitamin C from glucose.

  Here, the circadian rhythm of the plant autonomously continues a period of about 24 hours even under conditions where time information such as a light-dark cycle is not given. However, when vegetables (especially fruits and vegetables) are preserved in a dark environment where no light is irradiated, effects such as improvement in storage stability or increase in nutrients cannot be obtained because photosynthesis is not performed. On the other hand, when fruits and vegetables are stored in a bright environment that is continuously irradiated with light of the same radiant intensity, photosynthesis is carried out, but nutrients cannot be produced sufficiently, and the rate of photosynthesis and the ability of photosynthesis are reduced. It may induce disabilities such as

  Therefore, in the refrigerator 1 according to the present invention, as described above, the light emitting unit 14 of the vegetable compartment 500 emits light including visible light in the lower storage case 10 of the vegetable compartment 500 with a relatively high first. The first step of irradiating with radiant intensity and the second step of irradiating with a relatively low second radiant intensity are repeated alternately.

  For this reason, the lower storage case 10 has a bright period in which a visible light is irradiated with a relatively high intensity and becomes a bright environment, and a dark period in which a visible light is not irradiated with a relatively low intensity and becomes a dark environment. Changes over time. That is, in the lower storage case 10, an environment simulating a change in the amount of light in nature due to the rising of the sun in the morning and the setting of the sun at night is realized. Therefore, activities such as photosynthesis in accordance with the circadian rhythm can be promoted for plants such as fruits and vegetables put into the lower storage case 10.

  Here, photosynthesis is a reaction that requires light, and the higher the temperature, the better the efficiency. On the other hand, in order not to waste sugar generated by photosynthesis, the temperature should be low. In the refrigerator 1 according to the present invention, as described above, in the first step of irradiating light with a relatively high first radiation intensity, the internal temperature of the vegetable compartment 500 is set to a relatively high first temperature and compared. During the second step of irradiating light with a relatively low second radiation intensity, the internal temperature of the vegetable compartment 500 is set to a relatively low second temperature.

  Therefore, during the first step in which the light emission intensity is high and the photosynthesis of plants such as fruits and vegetables put into the lower storage case 10 of the vegetable room 500 is promoted, the temperature in the vegetable room 500 is increased to perform photosynthesis. Efficiency can be improved, and photosynthesis can be further promoted. Further, during the second step in which the light emission intensity is low and the photosynthesis of the fruits and vegetables in the upper storage case 11 is suppressed to facilitate the storage of sugar, the temperature in the vegetable compartment 500 is lowered to further preserve the sugar. Can be improved.

  In this way, by controlling the light irradiation and the temperature in the storage room in conjunction with each other according to the circadian rhythm of fruits and vegetables, it is possible to efficiently perform both photosynthesis and generation of nutrients and preservation of the generated nutrients. It is possible to obtain the effect of improving the storage stability of the vegetables during storage and increasing the nutrients. That is, according to the refrigerator 1 according to the present invention, it is possible to control activities such as photosynthesis of fruits and vegetables using the circadian rhythm of fruits and vegetables by irradiating light that simulates the movement of light in nature. It is possible to promote the production of nutrients by photosynthesis, suppress wasteful consumption of sugar obtained by photosynthesis and excessive transpiration, and preserve vegetables in high quality.

  When vegetables reach a temperature close to the freezing point, the molecules stored in the polymer are reduced in molecular weight, and the freezing point of their body fluids is lowered to prevent itself from freezing. Therefore, if the second temperature in the second step is set to about −1 to 0 ° C. close to the freezing point, the polysaccharide stored in the form of a polymer such as starch when cultivated in a field or the like. Is decomposed into monosaccharides, that is, glucose produced by photosynthesis, and can be used for synthesis of vitamin C and the like together with glucose produced after being stored in the vegetable compartment 500. Can be further planned.

  Further, as described above, the first duration time and the second duration time are set according to the season. Specifically, for example, the first duration time is the longest and the second duration time is about the summer solstice. The shortest time may be set so that the first duration is the shortest and the second duration is the longest at the time of the winter solstice. By doing in this way, the period of light and darkness becomes closer to nature, and it is possible to promote an increase in nutritional components of the vegetables being preserved.

  Furthermore, as described above, the first temperature and the second temperature may be set according to the season. Specifically, for example, in summer, the first temperature may be set in the range of 10 ° C. to 15 ° C. and the second temperature in the range of 5 ° C. to 10 ° C. By doing in this way, it can suppress that a low temperature disorder | damage | failure occurs in vegetables which are easy to generate | occur | produce low temperature disorders, such as eggplant and a cucumber, which are common in summer. Further, specifically, for example, in winter, the first temperature may be set in a range of 5 ° C. or more and 10 ° C. or less, and the second temperature may be set in a range of −1 ° C. or more and 5 ° C. or less. By doing in this way, it is possible to suppress transpiration of leafy vegetables that tend to wilt at high temperatures, such as spinach and komatsuna, which are common in winter, and to prevent leafy vegetables from being wilted.

  Here, the circadian rhythm of plants has a feature that the phase of the rhythm changes under the influence of ambient light. For example, when light is irradiated in a dark environment to create a bright environment, the rhythm phase shifts to the morning side. Utilizing such characteristics, the second process time is shorter than that of the first process, that is, the dark period is shorter than the light period, and the light irradiation cycle is set to 24 hours or less. The proportion of the time during which the fruits and vegetables in the case 10 perform photosynthesis during storage can be increased. And the generation | occurrence | production efficiency of nutrients, such as sugar of fruit and vegetables and vitamin C, can be improved by enlarging the ratio of the time which performs photosynthesis during a preservation | save.

  Here, the blue light has an action of opening the pores of the plant. Therefore, as shown in FIG. 6, the pores of the fruits and vegetables can be opened by irradiating light containing blue in the initial stage of the first step. Then, by continuing the light period after opening the pores of the fruits and vegetables, the fruits and vegetables can sufficiently take in carbon dioxide in the air and can efficiently perform photosynthesis. On the other hand, blue light also has an effect of promoting germination and flowering. For this reason, when aiming at long-term preservation of fruits and vegetables, it is better to shorten the time for irradiating blue light as much as possible.

  Therefore, in the first step of promoting photosynthesis, first, for example, after irradiating light containing blue for 10 minutes or more, the blue light emitting element is turned off and light not containing blue is irradiated. Photosynthesis can be performed after opening the pores of the fruits and vegetables in the storage case 10, and the photosynthesis of the fruits and vegetables in the lower storage case 10 can be further promoted.

  In addition, red light and green light can accelerate | stimulate the production | generation of the chlorophyll of vegetables, the production | generation of glucose by a biosynthesis function, and the synthesis | combination of vitamin C etc. using the same. For this reason, it is more efficient that the radiant intensity of blue light is lower than the radiant intensity of red light and green light. Specifically, for example, the radiant intensity of blue light is ¼ or less of the radiant intensity of red light and green light, preferably about 1/10 or more and 1/5 or less.

(Another specific example of night mode time zone)
In addition, about the time slot | zone which implements day mode (1st process) and night mode (2nd process), you may make it preset according to a season as mentioned above, but it is as follows. The determination may be made according to the open / close status of the vegetable compartment 500.

  As described above, the vegetable compartment door 9 is a door that can open and close the vegetable compartment 500 that is a storage compartment. The door opening / closing detection switch 12 is a detecting means for detecting opening / closing of the vegetable compartment door 9. The control device 8 counts the number of times of opening and closing the vegetable compartment door 9 detected by the door opening / closing detection switch 12 per fixed time, that is, per preset reference time. The reference time at this time is, for example, the second duration that is the duration of the second step (night mode).

  And the light emission control part 21 makes the light emission part 14 implement a 2nd process (night mode) in the time slot | zone when the frequency | count that the vegetable compartment door 9 was opened and closed per fixed time is below the preset frequency | count. Control. In addition, the temperature control unit 22 sets the internal temperature of the vegetable compartment 500 to the second temperature during the second step, that is, during a time period in which the number of times the vegetable compartment door 9 is opened and closed per predetermined time is equal to or less than the preset number. Control the cooling means.

  The door of the refrigerator 1 is often opened and closed before meal preparation or before and after shopping, and is not opened or closed while the user is sleeping or going out. Therefore, changes in the number of times the door is opened and closed in daily life can be patterned and predicted during the day. Therefore, the control device 8 counts the number of times the vegetable compartment door 9 is opened and closed, and stores, for example, in the storage unit 23 or the like, a time zone in which the number of times the door is opened and closed per fixed time is small. Then, by starting the second step 24 hours after the stored time zone or the time zone stored after the next day, the second step can be carried out in a time zone with a small number of times of opening and closing.

  If the vegetable compartment door 9 is opened and closed during the second step, the phase of the circadian rhythm of the stored fruits and vegetables may change due to the influence of light outside the refrigerator 1. Therefore, by performing the second step in a time zone where the number of times the vegetable compartment door 9 is opened and closed is small, it is possible to secure a dark period in which the fruits and vegetables in the lower storage case 10 are not irradiated with light, and to meet the circadian rhythm. The light irradiation control can be performed efficiently. Moreover, it can suppress that the vegetable compartment door 9 is opened and closed during a 2nd process, and external air penetrate | invades in the vegetable compartment 500, and can maintain low temperature.

  In addition, by operating the operation part 6a of the operation panel 6 installed in the refrigerator compartment door 7, the user performs the light irradiation control from the light emitting part 14 and stops (the light emitting part 14 is always turned off). You may enable it to switch. By enabling the user to select whether or not to perform control to turn on the light emitting unit 14 by the operation panel 6, the light emitting unit can be selected to stop when the fruits and vegetables are not stored for a long time or not used for a long period of time. 14 can always be turned off to reduce energy consumption and provide the same usability as a normal refrigerator 1. The same applies to the control of the cooling means by the temperature control unit 22.

  Further, during the light irradiation control, a display such as “light irradiation” may be performed on the display unit 6 b of the operation panel 6. Furthermore, the display unit 6b may display on the display unit 6b such as “lighting on” during the first step (light period) and “turning off” during the second step (dark period). Furthermore, the display unit 6b may be a display in which the state of light in the cabinet (in the vegetable compartment 500) is replaced with one day of natural light. Specifically, for example, the display unit 6b may display “daytime” during the first step, “night” during the second step, or the like in accordance with the step being performed in the light irradiation control. By doing in this way, a user can be notified about the state of the light in a warehouse, and convenience and satisfaction can be improved. In addition, the user can be cautioned not to open and close unnecessary doors during the second step.

  In addition, the operation panel 6 is not limited to be installed outside the refrigerator 1 but may be installed in a warehouse (storage room). Further, a communication means is provided in the refrigerator 1, and a command is transmitted to the control device 8 of the refrigerator 1 by a portable information terminal (a mobile phone including a smartphone, a tablet terminal, etc.) or an information of the refrigerator 1 through an electric communication line or the like. May be received and displayed. That is, the portable information terminal may be provided with one or both of the functions of the operation unit 6a and the display unit 6b of the operation panel 6.

  In addition, although the case where the light emission part 14 was made into RGB type white LED was demonstrated above, it is good also as what combined LED of monochromatic light. For example, red LED and green LED effective for chlorophyll activation, sugar and vitamin C increase, UV irradiation type LED for polyphenol increase, blue light LED for anthocyanin nutrient increase, etc. May be selected.

  Moreover, you may use LED with much ratio of the blue light which provided yellow fluorescent substance to blue LED. Thereby, since white light can be added, without making the blue light irradiated to vegetables run short, the visibility in the vegetable compartment 500 can be improved.

  The light intensity from the light emitting unit 14 (light quantity) may be dimmed so as to change gradually or stepwise. For example, the radiant intensity may be lowered during a time period corresponding to dawn, the radiant intensity may be increased during a period equivalent to noon, and the radiant intensity may be decreased during a period equivalent to evening. By doing in this way, a light quantity becomes closer to nature and a nutrient component increase can be promoted.

  In addition, the second radiation intensity that is the night mode radiation intensity (light quantity) may not be 0, and may be sufficiently dark compared to the first radiation intensity that is the day mode radiation intensity (light quantity). It may be turned on with a small amount of light such as moonlight. Further, a slight amount of light may be dimmed gradually or stepwise. By doing in this way, a light quantity becomes closer to nature and a nutrient component increase can be promoted.

  Furthermore, you may change the temperature in the vegetable compartment 500 gradually or in steps. For example, during a time period equivalent to dawn, the temperature is lowered, the temperature is increased after noon, or during a time period equivalent to about 2 pm, which is generally the highest temperature, and the temperature is decreased during a time period equivalent to evening. May be. Alternatively, the temperature may be lowered gradually or stepwise from the time zone corresponding to the evening so that the temperature during the time zone equivalent to the early morning is lowest. By doing in this way, temperature becomes closer to nature and it can promote an increase in nutrient content.

DESCRIPTION OF SYMBOLS 1 Refrigerator 2 Compressor 3 Cooler 4 Blower fan 5 Air path 6 Operation panel 6a Operation part 6b Display part 7 Refrigeration room door 7a Right door 7b Left door 8 Control apparatus 8a CPU
8b Memory 9 Vegetable room door 10 Lower storage case 11 Upper storage case 12 Door open / close detection switch 13 Thermistor 14 Light emission part 15 Opening part 21 Light emission control part 22 Temperature control part 23 Storage part 24 Timekeeping part 25 Season specific part 90 Heat insulation box 100 Refrigerated room 200 Switching room 300 Ice making room 400 Freezing room 500 Vegetable room 201 Switching room storage case 401 Freezing room storage case

Claims (5)

A storage room for storing food,
Cooling means for cooling the interior of the storage chamber;
A light emitting unit capable of irradiating visible light inside the storage chamber,
The light emitting unit
Performing a first step of irradiating light with a first radiation intensity for a first duration;
Performing a second step of irradiating light with a second radiation intensity lower than the first radiation intensity for a second duration;
The cooling means is
While the light emitting unit is performing the first step, the interior of the storage chamber is set to a first temperature,
The refrigerator which makes the inside of the store room into the 2nd temperature lower than the 1st temperature while the light-emitting part implements the 2nd process.   The refrigerator according to claim 1, wherein the first duration and the second duration are set according to a season.   The refrigerator according to claim 1 or 2, wherein the first temperature and the second temperature are set according to a season. The light emitting unit alternately performs the first step and the second step,
The refrigerator according to any one of claims 1 to 3, wherein a total of the first duration and the second duration is 24 hours or less. A door capable of opening and closing the storage room;
Detecting means for detecting opening and closing of the door,
The said light emission part implements a said 2nd process in the time slot | zone when the opening / closing frequency | count of the said door detected by the said detection means per preset reference time is below a preset frequency | count. The refrigerator as described in any one of Claims 4.

Images