DE112016004985T5 - fridge - Google Patents

Abstract

A refrigerator is provided which is capable of stimulating the photosynthesis of vegetables and fruits stored therein using a circadian rhythm of plants and taking into account a state of plant pores. For this purpose, a refrigerator (1) includes: a light-emitting area (14) capable of emitting visible light into the interior of a storage compartment (500) storing food; and a control part (8) configured to control the operation of the light emitting area for alternately repeating a visible light emission process to cause light containing visible light to be emitted from the light emitting area and a non-emission process to cause the visible light-containing light is not radiated from the light-emitting area. The light-emitting portion includes a first light source (16a) configured to emit light having a first wavelength of a visible light range as a central wavelength, and a second light source (16b) configured to emit light having a second wavelength of visible light range, which is different from the first wavelength, as a middle wavelength. In the visible light emission process, the control part controls the light emitting area such that a first irradiation process for causing light of both the first light source and the second light source to be irradiated, and a second irradiation process to cause light from only the first one Light source is emitted to be performed.

Description

area

This invention relates to a refrigerator.

background

As a conventional refrigerator, a refrigerator is known, which is provided with a receptacle for accommodating mainly leafy vegetables in a part inside a vegetable compartment, wherein a low-light irradiation device is disposed above the receptacle, the low-light device is a semiconductor light-emitting device Emitting light having a wavelength in the visible ray region, and the semiconductor light-emitting device is a red LED emitting a wavelength of about 660 nm (see, for example, Patent Document 1).

CITATION

patent literature

[Patent Document 1] JP 2002-267348 A

short version

Technical problem

However, in the conventional refrigerator shown in Patent Document 1, red light is continuously blasted on vegetables and fruits such as leafy vegetables (greens) for 24 hours a day. On the other hand, plants such as greens perform activities such as photosynthesis in a cycle of about 24 hours. This cyclic activity is referred to as a circadian rhythm. In photosynthesis using solar energy, the brightness and darkness of light significantly affect the circadian rhythm. Further, in the case of natural light, a wavelength of prevailing light changes with the passage of time of one day. Therefore, in a state in which red light having the same wavelength is continuously irradiated, vegetables and fruits such as leafy vegetables (greens) can not efficiently use the energy of emitted light. In particular, since at the time of performing the photosynthesis, pores of the vegetables and the fruits are not sufficiently opened, and carbon dioxide required for the synthesis can not be sufficiently absorbed, the photosynthesis efficiency deteriorates.

This invention has been made to solve such a problem, and it is an object to obtain a refrigerator capable of accelerating the photosynthesis of stored vegetables and fruits such as greens (especially leafy vegetables) by utilizing the circadian Rhythm of plants and taking into account the state of pores of plants.

the solution of the problem

A refrigerator according to the present invention includes: a storage compartment configured to store food; a light-emitting area capable of radiating visible light to the inside of the storage compartment; and a control part configured to control the operation of the light emitting area to alternately repeat a visible light radiation operation to cause light containing visible light to be emitted from the light emitting area and a nonradiation process to cause the light containing visible light to not is emitted from the light-emitting portion, the light-emitting portion comprising: a first light source configured to emit light having a first wavelength of a visible light range as a central wavelength; and a second light source configured to emit light having a second wavelength of the visible light region different from the first wavelength than a central wavelength, wherein the control part is configured to control, in the visible light emission process, the light emitting A region for performing a first irradiation process for causing light to be emitted from both the first light source and the second light source and a second irradiation process for causing light to be emitted only from the first light source.

Advantageous effect of the invention

In a refrigerator according to this invention, an advantageous effect is obtained in that it is possible to accelerate the photosynthesis of stored vegetables and fruits such as greens (especially leafy vegetables) by utilizing the circadian rhythm of plants and taking into account the state of pores of the plants.

list of figures

• 1 Fig. 10 is a front view of a refrigerator related to a first embodiment of the present invention.
• 2 Fig. 15 is a longitudinal sectional view of the refrigerator relating to the first embodiment of the present invention.
• 3 is a diagram that enlarges a vegetable compartment in 2 shows.
• 4 FIG. 15 is a diagram showing a configuration of a light emitting area provided with the refrigerator related to the first embodiment of the present invention.
• 5 Fig. 10 is a block diagram showing a configuration of a control system of the refrigerator related to the first embodiment of the present invention.
• 6 Fig. 10 is a time chart of the light emission control of each light source to which the light emitting portion of the refrigerator related to the first embodiment of the present invention is applied.
• 7 Fig. 10 is a flowchart showing a flow of the light emission control of the refrigerator related to the first embodiment of the present invention.
• 8th Fig. 12 is a graph showing a comparative example between amounts of vitamin C in a case where cabbage is stored for three days under a plurality of light irradiation conditions.
• 9 Fig. 10 is a time chart of the light emission control of each light source provided with the light emitting portion of the refrigerator related to the first embodiment of the present invention and of opened / closed states of a vegetable compartment door.

Description of the embodiment

An embodiment for carrying out this invention will be described with reference to accompanying drawings. In each of the drawings, the same reference numerals are given to the same or corresponding parts, and an overlapping description is appropriately simplified or omitted. The present invention is not limited to the following embodiment and can be variously modified within a range not departing from the spirit of the present invention.

First embodiment

The 1 to 9 refer to a first embodiment of this invention. 1 is a front view of a refrigerator; 2 is a longitudinal sectional view of the refrigerator; 3 is a diagram that enlarges a vegetable compartment in 2 shows; 4 Fig. 12 is a diagram showing a configuration of a light-emitting area provided with the refrigerator; 5 Fig. 10 is a block diagram showing a configuration of a control system of the refrigerator; 6 Fig. 11 is a time chart of a light emission controller of each light source provided with the light emitting portion of the refrigerator; 7 Fig. 10 is a flowchart showing a flow of the light emission control of the refrigerator; 8th Fig. 15 is a graph showing a comparative example between amounts of vitamin C in a case where cabbage is stored for three days under a plurality of light-emitting conditions; and 9 Fig. 10 is a time chart of the light emission control of each light source provided with the light emitting portion of the refrigerator and open / closed states of a vegetable compartment door.

In each figure, a dimensional relationship, shape and the like of each component may be different from the actual one. Further, positional relationships (for example, a vertical positional relationship and the like) between components are, in principle, those in which the refrigerator is installed in a use state.

(Configuration of the refrigerator)

A fridge 1 according to the first embodiment of this invention has a heat-insulating box body 90 , as in 2 is shown. The front of the heat-insulating box body 90 is open, and storage space is formed in this. The heat-insulating box body 90 has an outer box, an inner box and heat-insulating material. The outer box is made of steel. The inner box is made of resin. The inner box is located inside the outer box. The heat-insulating material is, for example, urethane foam or the like and is filled in the space between the outer box and the inner box. The inside of the heat-insulating box body 90 formed space is divided into several storage compartments for receiving and storing food by one or more dividing parts.

As in the 1 and 2 shown here is the fridge 1 with for example a cooling compartment 100 , a switch box 200 , an ice-making compartment 300 , a freezer 400 and a vegetable compartment 500 as the multiple memory slots provided. These storage bins are in a four-stage vertical configuration in the heat-insulating box body 90 arranged.

The cooling compartment 100 is in the uppermost stage of the heat-insulating box body 90 arranged. The switch box 200 is on one of the left and right sides below the cooling compartment 100 arranged. A Cooling temperature zone of the switching compartment 200 can be switched by selecting any of several temperature zones. The multiple temperature zones, called the cooling temperature zone of the switching compartment 200 can be selected, for example, a freezing temperature zone (for example, about -18 ° C), a cooling temperature zone (for example, about 3 ° C), a cold-temperature zone (for example, about 0 ° C), a light freezing temperature zone (for example, about -7 ° C) and the like , The ice making compartment 300 is laterally adjacent to the switching compartment 200 arranged parallel to the switching compartment 200, that is, on the other from the left and the right side below the cooling compartment 100 ,

The freezer 400 is below the switch box 200 and the ice-making compartment 300 arranged. The freezer 400 is mainly for use at the time of freezing a memory object for a relatively long time. The vegetable compartment 500 is in the lowest step below the freezer 400 arranged. The vegetable compartment 500 is mainly used to hold vegetables, a large PET bottle with a large volume (for example 2L or the like) and the like.

An opening area in front of the refrigerator compartment 100 is formed with a refrigerator compartment door 7 provided by the pivot type to open / close the opening area. Here is the refrigerator compartment door 7 of the double swing type and is with a right door 7a and a left door 7b configured. On an outside surface of the refrigerator compartment door 7 (eg the left door 7b ) on the front of the refrigerator 1 is a control panel 6 arranged. The control panel 6 is provided with an operation area 6a and a display area 6b. The operation section 6a is an operation switch for setting a cooling temperature for each storage compartment and an operation mode (a defrosting mode or the like) of the refrigerator 1 , The display area 6b is a liquid crystal display for displaying various kinds of information such as the temperature of each storage compartment. Furthermore, the control panel 6 be provided with a touch panel serving as both the operating portion 6a and the display portion 6b.

Each of the storage compartments, the other than the cooling compartment 100 are (the switching box 200 , the ice-making compartment 300 , the freezer 400 and the vegetable compartment 500 ) is opened / closed by a drawer type door. The drawer type door may be in a depth direction (a front-back direction) of the refrigerator 1 can be opened and closed by causing a frame fixedly attached to the door to slide relative to horizontally formed rails on the left and right inner wall surfaces of each storage compartment.

Furthermore, within the switching compartment 200 and inside the freezer 400 a changeover receptacle 201 and a freezer receptacle 401 capable of internally receiving food and the like, each taken in a pull-out manner. In the same way are inside the vegetable compartment 500 a receptacle 11 the upper stage and a receptacle 10 the lower stage, which are able to accommodate internally food and the like, taken in a pullout manner.

(Cooling Mechanism)

The refrigerator 1 is provided with a freeze cycle that cools air to be delivered to each storage compartment. The freeze cycle is with a compressor 2 a condenser (not shown), a throttle device (not shown), a radiator 3 and the like configured. The compressor 2 compresses refrigerant in the freeze cycle and outputs it. The condenser causes that from the compressor 2 discharged refrigerant condenses. The throttle device causes the refrigerant flowing out of the condenser to expand. The cooler 3 The air to be supplied to each storage compartment cools the refrigerant expanded by the throttle device. The compressor 2 for example, in a lower part on the back of the refrigerator 1 arranged.

In the fridge 1 is an air passage 5 for supplying air cooled by the freezing cycle cycle to each storage compartment. This air passage 5 is mainly on the back inside the fridge 1 arranged. The cooler 3 the freeze cycle is installed in this air passage 5. Furthermore, inside the air passage 5 also a fan 4 to deliver by the radiator 3 cooled air to each storage compartment installed.

If the blower 4 is in operation, is through the radiator 3 cooled air (cold air) through the air passage 5 to the freezer 400 , the switch box 200 , the ice-making compartment 300 and the refrigerated compartment 100 sent to cool the inside of these storage compartments. The vegetable compartment 500 is by inserting from the refrigerator compartment 100 returning cold air via a return air passage for the refrigerated compartment in the vegetable compartment 500 cooled. The cold air, the vegetable compartment 500 is through a recirculation air passage for the vegetable compartment (these return air passages are not shown) in the air passage 5 returned, in which the cooler 3 exist. Then the air from the radiator 3 cooled again, and the cold air circulates inside the refrigerator 1 ,

At a position on the way from the air passage 5 to each memory compartment a damper, not shown, is arranged. Each damper opens / closes a position of the air passage 5 which is connected to each storage compartment. By changing an opening / closing state of the damper, the amount of cold air supplied to each storage compartment can be adjusted. Furthermore, the temperature of the cold air can be controlled by controlling the operation of the compressor 2 be set.

The one with the compressor 2 and the radiator 3 , the blower 4 , the air passage 5 and the freezing cycle circuit configured as described above, forms a cooling means for cooling the inside of the storage compartments.

For example, in an upper part of the back of the refrigerator 1 a control device 8th added. The control device 8th is provided with a control circuit or the like to perform various controls necessary for the operation of the refrigerator 1 required are. As the control circuit with which the control device 8th is, for example, a circuit for controlling the operation of the compressor 2 and the blower 4 , and the degree of opening of the dampers based on the temperature within each storage compartment, from into the actuation panel 6 input information and the like given. That is, the control device 8th controls the operation of the refrigerator 1 by controlling the above-described cooling means and the like. The temperature within each storage compartment may be detected by a thermistor (not shown) or the like installed in the storage compartment.

(Configuration of the vegetable compartment)

3 is a cross-sectional view of the vegetable compartment 500 that contains the refrigerator 1. The vegetable compartment 500 is a storage compartment that stores food, especially vegetables. The receptacle 10 the lower level is through a frame (not shown) of a vegetable compartment door 9 supported. On the upper side of the receptacle 10 the lower stage is the receptacle 11 the upper level. If the vegetable compartment door 9 is pulled out in the forward direction, the receptacle 10 the lower stage and the receptacle 11 the upper level, with the vegetable compartment door 9 combined, pulled out in the forward direction. If only the receptacle 11 the upper stage slides backwards while the vegetable compartment door 9 is in the pulled-out state, a state in which only the receptacle 10 the lower stage is pulled out. In the state in which only the receptacle 10 The lower stage is pulled out, food can from the receptacle 10 taken from the lower stage or put into this.

Inside the vegetable compartment 500 are a door opening / closing detection switch 12, a thermistor 13 and a light emitting area 14 arranged. The door opening / closing detection switch 12 is for detecting an open / closed state of the vegetable compartment door 9 , The door opening / closing detection switch 12 is disposed at a position that the vegetable compartment door 9 in an edge region of a front opening of the vegetable compartment 500 faces.

The thermistor 13 and the light emitting area 14 are at a rear area inside the vegetable compartment 500 appropriate. The thermistor 13 records the temperature inside the vegetable compartment 500 , The light emitting area 14 is capable of visible light in the interior of the vegetable compartment 500 A storage compartment is to broadcast. Here is an opening area 15 in a part of the light-emitting area 14 on the back of the receptacle 10 the lower stage is formed formed. The light emitting area 14 is configured, visible light through this opening area 15 into the interior of the receptacle 10 to broadcast the lower level. Material having a property for effecting that of the light emitting area 14 emitted visible light is allowed to pass for at least a part corresponding to the opening area 15 of the receptacle 10 the lower level can be used.

(Configuration of the light emitting area)

Next, a configuration of the light-emitting area will be described 14 regarding 4 described. As in 4 is shown is the light-emitting area 14 provided with two types of light sources, a first light source 16a and a second light source 16b , As described above, the light emitting area is 14 able to emit visible light. Therefore, the light-emitting area 14 provided with sources of visible light that emit visible light. The first light source 16a and the second light source 16b are the sources of visible light.

The first light source 16a emits light having a first wavelength as a medium wavelength. The second light source 16b emits light having a second wavelength as a medium wavelength. Both the first wavelength and the second wavelength belongs to a visible light range. However, the second wavelength is different from the first wavelength.

Specifically, the first wavelength, which is the mean wavelength of the first light source 16a is between 500 nm and 700 nm including 500 nm and 700 nm, preferably between 600 nm and 700 nm including 600 nm and 700 nm. That is, from the first light source 16a emitted light is red. That is, for example, it may be a red LED as the first light source 16a be used.

Furthermore, the second wavelength, which is the mean wavelength of the second light source 16b is between 400 nm and 500 nm including 400 nm and 500 nm. That is, from the second light source 16b emitted light is blue. That is, for example, it may be a blue LED as the second light source 16b be used.

The first light source 16a and the second light source 16b are configured so that each of them can be turned on and off independently.

(Control system of the refrigerator)

5 FIG. 12 is a block diagram illustrating a functional configuration of a control system of the refrigerator. FIG 1 shows. In 5 In particular, such parts are on the control of the vegetable compartment 5 are shown. The control device 8th is, for example, a microcomputer and a processor (CPU: central processing unit) 8a and a memory 8b Mistake. Through the processor (CPU) 8a who is in the store 8b executes stored program, performs the control device 8th a previously set process to the refrigerator 1 to control.

A detection signal for the temperature inside the vegetable compartment 500 is from the thermistor 13 into the control device 8th entered. An operation signal of operating portion 6a of the operation panel 6 will also be in the control device 8th entered. Furthermore, a detection signal from the door opening / closing detection switch 12 is also input to the control device 8.

Based on an inputted signal, the controller performs 8th a process of controlling operations of the compressor 2 , the blower 4 and the like so through, that the inside of the vegetable compartment 500 remains at a set temperature. Furthermore, the control device gives 8th an indication signal to the display area 6b of the operation panel 6 out.

Furthermore, the control device gives 8th a control signal to the light emitting area 14 to also control the light-emitting operation of the light-emitting area 14 to control. As described above, the light emitting area is 14 with the first light source 16a and the second light source 16b Mistake. Each of these two types of light sources can be turned on and off independently. The control device 8th can ON / OFF states of the first light source 16a and the second light source 16b , with which the light emitting area 14 is provided to control independently.

(Control of the light emitting area)

Next, the control of the light-emitting operation of the light-emitting area will be described 14 through the control device 8th regarding 6 described. The control device 8th controls the operation of the light-emitting area 14 to alternately irradiate a visible light to cause light containing visible light from the light emitting area 14 is emitted, and a non-radiating operation for causing light containing visible light not from the light-emitting area 14 is broadcast, to repeat. In the visible light emission process, at least one of the first light source becomes 16a and the second light source 16b switched on. In the non-broadcast process, neither the first light source 16a still the second light source 16b switched on.

The visible light emission process is further divided into two processes. In the visible light emission process, a first broadcasting operation is first performed, and then a second broadcasting process is performed. That is, the control device 8th controls the light emitting area 14 such that it performs the first emission process and the second emission process in the visible light emission process. In the first broadcasting process, the controller causes 8th that light from both the first light source 16a as well as the second light source 16b is broadcast. That is, both the red light and the blue light are emitted. In the second broadcasting operation, the control device causes 8th that light only from the first light source 16a is emitted and the second light source 16b is off. That is, only red light is emitted, and blue light is not emitted.

A time duration of each operation is set in advance. The duration of the first broadcast, the duration of the second broadcast, and the duration of the first broadcast Non-radiating operation is assumed as ΔT1 and ΔT2 and ΔT3, respectively.

Thus, the control device controls 8th the light emitting area 14 such that the first broadcasting process, the second broadcasting process and the non-broadcasting process are performed in this order. Then, after the non-irradiation operation is completed, each process is repeatedly performed again in the above-described order by the visible-light irradiation, that is, the first irradiation process. Therefore, the time ΔT required to perform one cycle of each operation in the order is the total of ΔT1, ΔT2, and ΔT3. Furthermore, the duration of the visible light emission process is the sum total of ΔT1 and ΔT2.

The control device 8th controls the light emitting area 14 such that the visible light emission process and the non-emission process are alternately repeated in a cycle of 14 hours or shorter. That is, ΔT is set to be twenty-four hours or shorter. Further, the time period ΔT3 of the non-radiating operation is set to be equal to or shorter than the period of the visible light emission process. That is, the period of non-radiating operation ΔT3 is set to be equal to or shorter than the total sum of the period of time ΔT1 of the first broadcasting operation and the period of time ΔT2 of the second broadcasting process. Further, the time period ΔT1 of the first broadcasting operation is set to be equal to or shorter than the period of time ΔT2 of the second broadcasting process. As an example of the time duration of each operation satisfying the above-described conditions, ΔT1, ΔT2 and ΔT3 are specifically set to two hours, ten hours and eight hours, respectively. In this case, ΔT is twenty hours.

It will take a series of steps to control the light emitting area 14 of the vegetable compartment 500 with which the refrigerator configured as described above 1 is provided with reference to the flowchart of 7 described. If the fridge 1 is turned on, causes the control device 8th in step S101 first, that the first light source 16a and the second light source 16b of the light emitting area 14 be turned on. In the next step S102, the controller sets 8th returns a value t of a timer which measures the elapsed time to 0 and starts timing by the timer.

Then, in the next step S103, the control device confirms 8th Whether the elapsed time t of the timer has reached ΔT1 or not. If the elapsed time t of the timer has not yet reached ΔT1, the controller repeats 8th the confirmation in step S103 until the elapsed time t of the timer reaches ΔT1. Then, when the elapsed time t of the timer reaches ΔT1, the controller goes 8th to step S104. The aforementioned steps S101 to S103 are the first broadcasting process.

In step S104, the control device causes 8th in that the second light source 16b of the light emitting area 14 is switched off. Therefore, a state is obtained in which only the first light source 16a is turned on. In the next step S105, the controller sets 8th the value t of the timer, which measures the elapsed time, back to 0 and starts timing by the timer.

Then, in the next step S106, the control device confirms 8th Whether the elapsed time t of the timer has reached ΔT2 or not. When the elapsed time t of the timer has not reached ΔT2, the controller repeats 8th the confirmation in step S106 until the elapsed time of the timer reaches ΔT2. Then, when the elapsed time of the timer reaches ΔT2, the controller goes 8th to step S107. The aforementioned steps S104 to S106 are the second broadcasting operation.

In step S107, the controller causes 8th that the first light source 16a of the light emitting area 14 is turned off. Therefore, a state is obtained in which both the first light source 16a as well as the second light source 16b are turned off. Then, after proceeding to step S108, the controller sets 8th the value t of the timer, which measures the elapsed time, back to 0 and starts timing by the timer.

In the next step S109, the control device confirms 8th whether the elapsed time of the timer has reached ΔT3 or not. If the elapsed time t of the timer has not reached ΔT3, the controller 8 repeats the affirmation in step S109 until the elapsed time t of the timer reaches ΔT3. Then, when the elapsed time t of the timer reaches ΔT3, the controller returns 8th to step S101 and repeatedly performs the aforementioned steps. The aforementioned steps S107 to S109 are the non-irradiation operation.

(Operation by light emission control)

Next, the light emission control by the above-described light emitting control of the light emitting area 14 expected operation described. First, there is a circadian rhythm plants autonomously continue a cycle of about twenty-four hours even under a condition that time information such as a light-dark cycle of light is not given. However, in the case of storing vegetables and fruits such as greens (especially vegetables and fruits) in a dark environment in which light is not emitted, the photosynthesis is not performed, and therefore, an improvement in storability, an increase in the amount of nutrients or the like can not be obtained. On the other hand, in the case of storing vegetables and fruits in a light environment in which light is continuously emitted, photosynthesis is performed, but problems such as nutrients are not sufficiently generated and the speed of photosynthesis or photosynthetic ability deteriorate, can occur.

Therefore, in the refrigerator 1 according to this invention, the light emitting area 14 of the vegetable compartment 500 the visible light emission process for emitting light containing visible light into the interior of the receptacle 10 the lower level of the vegetable compartment 500 and the non-irradiation process in which the light containing visible light is not irradiated, wherein the above-described operations are alternately repeated.

Therefore, the inside of the receptacle becomes 10 the lower stage between a light period during which the visible light is emitted to obtain the light environment and a dark period during which the visible light is not radiated to obtain the dark environment, switched over time. That is, inside the receptacle 10 the lower level is created an environment in which a change of the amount of light in the natural world, which is caused by the sunrise in the morning and the sunset in the evening, is simulated. Therefore, it is possible to act on plants so that vegetables and fruits that are in the receptacle 10 the lower stage, perform activities such as photosynthesis according to the circadian rhythm.

The photosynthetic reaction of plants is described here. The photosynthetic reaction can be expressed by the following expression ( 1 ). 6CO ₂ + 12H ₂ O + 688kcal → C ₆ H ₁₂ O ₆ + 6H ₂ O + 6O ₂ (1)

In this expression ( 1 ) are CO ₂ , H ₂ O, 688kcal and C ₆ H ₁₂ O ₆ carbon dioxide, water, light energy and glucose, respectively.

By the photosynthetic reaction according to this expression ( 1 ) plants produce oxygen and sugar from carbon dioxide in the atmosphere and water contained in the plants using light energy. This reaction is divided into two stages. The first stage decomposes water into hydrogen and oxygen using light energy absorbed by pigments such as chlorophyll contained in leaves and the like and stores chemical energy having the function of enzyme protein. The second stage synthesizes glucose using electrons, hydrogen ions and carbon dioxide in the atmosphere. In vegetables in which glucose has increased, their storability is improved and vitamin C is produced from the glucose.

In order to cause the photosynthesis to be carried out actively, it is necessary that the inside of the vegetable compartment 500 emitted light is effective for photosynthesis. An absorption spectrum of chlorophyll has two light absorption peaks in red (near 660 nm) and blue (near 450 nm), and it is known that these wavelengths are particularly effective for photosynthesis. When green ( 500 to 600 nm), although the absorption rate by chlorophyll is low, light is scattered within a leaf, and the frequency of incidence with chlorophyll becomes high. Therefore, the absorbency of the whole sheet becomes high.

Furthermore, blue light has a function of opening pores of plants. Therefore, by emitting light containing blue in the initial stage of the light period during which light is emitted, it is possible to open pores of vegetables and fruits. By continuing the light period after opening the pores of the vegetables and fruits, the vegetables and fruits can absorb enough carbon dioxide from the air and can efficiently carry out the photosynthesis. On the other hand, blue light also has a function of accelerating germination and blooming. Therefore, in the case of intending prolonged storage of vegetables and fruits, it is better to shorten the time of blue light irradiation as much as possible.

In the process of emitting visible light to accelerate the photosynthesis, the second light source becomes 16b first turned on to emit light containing blue in the first irradiation process, and thereafter the second light source 16b turned off to emit in the second irradiation process light that does not contain blue. This makes it possible after the pores of vegetables and fruits inside the receptacle 10 the lower stage were opened to effect the execution of the photosynthesis, and it is possible the photosynthesis of the Vegetables and fruits inside the receptacle 10 to accelerate the lower stage further. Further, at this time, it is possible to make the first irradiation process by irradiating blue-containing light shorter than the second irradiation process by emitting non-blue light light as much as possible to prevent germination and blooming from accelerating and to obtain a sufficient pore opening function.

The circadian rhythm of plants has a cycle of about twenty-four hours, corresponding to the hours from morning to night and then again until morning. However, the circadian rhythm of plants has a characteristic that the phase of the rhythm changes depending on the influence of ambient light. For example, when light is emitted in the dark environment to preserve the bright environment, the rhythm phase shifts to the morning side. By using such a characteristic, in order to make the time for the non-irradiation process shorter than that for the visible light emission, that is, the dark period in which light is not irradiated, is shorter than the light period in which light is emitted is to make, so that a light emission cycle is equal to or shorter than twenty-four hours, it is possible to increase the rate of time during the vegetables and fruits inside the receptacle 10 the lower stage during their storage perform the photosynthesis. By increasing the rate of time during which vegetables and fruits perform photosynthesis while stored, it is possible to improve the efficiency of producing nutrients from vegetables and fruits such as sugar and vitamin C.

It is described herein which differences in the amount of a nutrient (vitamin C) contained in the vegetables and fruits occur when the vegetables and fruits are stored under a plurality of different light irradiation conditions as described above, by referring to a specific comparative example with reference to FIG 8th is given. 8th Figure 12 is a graph comparing amounts of Vitamin C after cabbage has been stored for three days under several different light irradiation conditions. The amounts of vitamin C are indicated by rates of change when the initial amounts of vitamin C are stored before storage 100 be. With respect to the light irradiation conditions, the light intensity is the same, and the color contained in the emitted light and the irradiation time per day are changed.

In non-irradiation, where no light is emitted throughout the day, the amount of vitamin C after storage decreases relative to the initial amount (the left-most graph) 8th ). In comparison, under all conditions in which light is emitted, the amount of vitamin C after storage increases in comparison with the initial amount. When a comparison is made between conditions under which light is continuously emitted throughout the day, the amount of increase in vitamin C after storage in the case of combining red light and blue light (the third from the left in FIG 8th ) larger than in the case of radiating only red light (the second from the left in FIG 8th ).

Further, when the time during which light is not radiated, that is, the dark period is provided to perform light irradiation in accordance with the circadian rhythm, a result is obtained in which the amount of increase of vitamin C after storage becomes much larger is (the rightmost diagram in 8th ). Thus, by irradiating light of a proper wavelength according to the circadian rhythm of vegetables and fruits, it is possible to make the photosynthesis and the production of nutrients effective, and it is possible to have an effect of improving storability and increase to get the amount of nutrients from stored vegetables. That is, with the fridge 1 According to this invention, it is possible to take advantage of the circadian rhythm of vegetables and fruits to control activities of vegetables and fruits such as photosynthesis, by performing a light irradiation that simulates the movement of light in the natural world. This makes it possible to store vegetables of high quality by accelerating the production of nutrients through photosynthesis or suppression of excessive perspiration.

(Other Example of Control of Light Emitting Area)

In the above-described control of the light-emitting area 14 is not particularly mentioned in which time slots of a day the visible light emission process, the non-emission process and the like are performed. Here is another example of the control of the light-emitting area 14 an example of performing the control of the light-emitting area 14 as for a time slot in which the non-irradiation operation is to be performed, according to a detection result of an open / closed state of the vegetable compartment door 9 regarding 9 described.

As described above, the vegetable compartment door is 9 a door that is capable of the vegetable compartment 500 which is a storage compartment, open and close. Further, the door opening / closing detection switch 12 is detecting means for detecting the opening and closing of this vegetable compartment door 9 , The control device 8th counts the number of times open / close the vegetable compartment door 9 detected by the door opening / closing detection switch 12 in a predetermined time, that is, in a preset reference time. The reference time is, for example, the time duration ΔT3 of the non-radiating operation. The control device 8th controls the light emitting area 14 to perform the non-broadcasting operation in a time slot in which the number of times of opening and closing the vegetable compartment door 9 is equal to or lower than a number of times previously set per predetermined time.

The door of the refrigerator 1 is often opened and closed before and after preparing meals or shopping, and is not opened or closed while a user is sleeping or out of the house. Therefore, in daily life, a pattern for changing the number of times of opening and closing the door during one day can be created and predicted. Therefore, the control device counts 8th the number of times open and close the vegetable compartment door 9 and stores a time slot in which the number of times of opening and closing the door is small per predetermined time, in a memory area not shown, or the like. Then, by starting the non-broadcasting operation in the stored time slot on the next and subsequent days or twenty-four hours after the storage of the time slot, the non-broadcasting operation may be performed in the time slot in which the number of times of opening and closing is small.

If the vegetable compartment door 9 During the non-irradiation process, it is possible for the phase of the circadian rhythm of stored vegetables and fruits to change due to the influence of light outside the refrigerator 1 , Therefore, by performing the non-irradiation operation in a time slot in which the number of times of opening and closing the vegetable compartment door is performed 9 small, possible to ensure a dark period, in the light not on vegetables and fruits inside the receptacle 10 the lower stage is irradiated, and it is possible to effectively perform the light emission control according to the circadian rhythm.

It is also possible to allow the user between performing the control of non-emission from the light-emitting area 14 and the termination of the control (which causes the light emitting area 14 is switched off continuously) by the operating portion 6a of the refrigerator compartment door 7 installed actuating panel 6 is pressed. By allowing the user to select whether the controller is to turn on the light-emitting area 14 through the actuating panel 6 or not, it is possible to select the termination to cause the light-emitting region 14 is switched off continuously, if not much vegetables and fruits are stored or use for a long time does not take place to reduce energy consumption, and it is possible to obtain a usability similar to that of a conventional refrigerator.

Further, while the light emission control is being performed, a display such as "during the light emission" may be displayed on the display area 6b of the operation panel 6 to be shown. Further, a display such as "light is on" and a display such as "light is off" may be displayed on the display area 6b during the visible light (light period) or non-light (dark period). Furthermore, a display in the states of light inside the refrigerator (inside the vegetable compartment 500 ) are replaced by a day of light in the natural world on which display area 6b is shown. More specifically, for example, according to a process performed in the light emission control, a display such as "morning,""daytime," and "night" may be displayed on the display area 6b during the first broadcasting operation, the second broadcasting operation, and the non-broadcasting operation. This makes it possible to inform the user of the state of the light inside the refrigerator and to improve the convenience and feeling of satisfaction. In addition, it is also possible to inform the user that he is careful not to unnecessarily open or close the door while the non-broadcasting operation is being performed.

The actuating panel 6 is not limited to being installed on the outside of the refrigerator but may be installed inside the refrigerator (inside a storage compartment). Furthermore, communication means for the refrigerator 1 be provided, so that an instruction to the control device 8th of the refrigerator 1 can be transferred, and information about the refrigerator 1 may be provided by a mobile information terminal (including a cellphone) Smartphone, a tablet terminal or the like) via a telecommunication line or the like can be received and displayed. That is, the mobile information terminal can operate with one or both functions of the operation area 6a and the display area 6b of the operation panel 6 be provided.

Industrial Applicability

This invention can be applied to a refrigerator provided with a light emitting area in a storage compartment for storing food, wherein visible light is radiated from the light emitting area into the inside of the storage compartment.

LIST OF REFERENCE NUMBERS

1

fridge

2

compressor

3

cooler

4

fan

5

Air passage

6

operation panel

7

Cooling compartment door

7a

right door

7b

left door

8th

control device

8a

CPU

8b

Storage

9

Vegetable compartment door

10

Receptacle of the lower stage

11

Receptacle of the upper level

12

Open / close detection switch

13

thermistor

14

light emitting area

15

opening area

16a

first light source

16b

second light source

90

heat insulating box body

100

freezer

200

Umschaltfach

300

ice-making

400

refrigeration specialist

500

crisper

201

Umschaltfach receptacle

401

Refrigeration specialist receptacle

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• JP 2002267348 A [0003]

Claims (7)

Refrigerator, which has: a storage compartment configured to store food; a light emitting area capable of emitting visible light into the interior of the storage area; and a control part configured to control the operation of the light-emitting region to alternately repeat a visible light emission process to cause light containing visible light to be emitted from the light-emitting region, and a non-emission process to cause the light containing visible light to not is emitted from the light emitting area; wherein the light-emitting region comprises: a first light source configured to emit light having a first wavelength of a visible light range as a central wavelength; and a second light source configured to emit light having a second wavelength of the visible light region different from the first wavelength as a middle wavelength; the control part is configured to control, in the visible light emission process, the light emitting region to perform a first emission process to cause light to be emitted from each of the first light source and the second light source, and a second emission process to cause light only emitted from the first light source. Refrigerator after Claim 1 in which the first wavelength is between 500 nm and 700 nm including 500 nm and 700 nm. Refrigerator after Claim 1 or 2 in which the second wavelength is between 400 nm and 500 nm containing 400 nm and 500 nm. Refrigerator after one of the Claims 1 to 3 in which the control part controls the light-emitting area so that the visible-light radiating operation and the non-radiating operation are alternately repeated in a cycle of 24 hours or less. Refrigerator after one of the Claims 1 to 4 in which the duration of the non-broadcasting operation is equal to or shorter than the total sum of the duration of the first broadcasting operation and the duration of the second broadcasting operation. Refrigerator after one of the Claims 1 to 5 in which the time duration of the first broadcasting operation is equal to or shorter than the period of the second broadcasting process. Refrigerator after one of the Claims 1 to 6 , further comprising: a door capable of opening and closing the storage compartment; and detection means configured to detect the opening and closing of the door; wherein the control part controls the light-emitting area to perform the non-broadcasting operation in a time slot in which the number of times of opening and closing the door detected by the detection means in a predetermined reference time is equal to or smaller than a predetermined number of painting is.

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