JP2016023830A - Refrigerator and home electric appliance network system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To display a storage chamber internal image to meet a terminal owner's preference on an information terminal.SOLUTION: Communication means controls a luminous color or brightness of a storage chamber internal lamp in response to a content of a command from an information terminal in a case in which an imaging unit picks up a storage chamber internal image.SELECTED DRAWING: Figure 5

Description

  Embodiments of the present invention relate to a refrigerator and a home appliance network system.

  Some refrigerators include an imager. This image pickup device picks up an image inside the storage room, which is an image inside the storage room, with the inside lamp turned on, and the image pickup result of the inside image is transmitted to the information terminal via the Internet network. This information terminal is carried by the owner of the refrigerator, and displays it on its own display in response to receiving the imaging result of the internal video.

JP 2012-226748 A

  In the case of a conventional refrigerator, since the interior light is turned on with a constant illuminance and a constant emission color when capturing the interior image, the appearance of the interior image of the information terminal tends to be uniform. there were.

  The refrigerator of the embodiment includes an interior lamp that illuminates a storage room, an imager that captures an interior image that is an image in the storage room, and an electrical controller that electrically controls the interior light. The control means for turning on the interior lamp when the interior image is imaged, and the image capture result of the interior image by the imager are transmitted to the external information terminal in response to the information terminal. When a command is transmitted from the information terminal, the communication unit is configured to display the imaging result of the internal video, and the control unit includes the communication unit that captures the video inside the cabinet. It is characterized in that the emission color or brightness of the interior lamp is controlled in accordance with the content of the command from the information terminal received by the communication means.

The figure which shows Example 1 (The figure which shows a refrigerator) Diagram showing the electrical configuration of the refrigerator The figure which shows a refrigerator compartment (a is Xa view, b is sectional drawing which follows Xb line) Diagram showing refrigerator network The figure which shows the imaging processing of the communication control circuit Figure showing information terminal screen FIG. 5 equivalent diagram showing the second embodiment. 6 equivalent diagram FIG. 5 equivalent diagram showing Example 3. 6 equivalent diagram

  The refrigerator 1 of FIG. 1 has a refrigerator compartment 2 formed therein. The refrigerator 1 has a refrigeration cycle 3 (see FIG. 2), and cold air is supplied from the refrigeration cycle 3 into the refrigerator compartment 2. The refrigerator compartment 2 has an open front and corresponds to a storage compartment. A left door 4 and a right door 5 are mounted in front of the refrigerator compartment 2. The left door 4 is rotatable around a vertical axis at the left end, the right door 5 is rotatable around a vertical axis at the right end, and the front of the refrigerator compartment 2 is The left door 4 and the right door 5 are opened and closed in response to a rotation operation. A plurality of shelf boards 6 are mounted in the refrigerator compartment 2. The plurality of shelf boards 6 are transparent ones arranged at intervals in the vertical direction, and food is placed on each upper surface of the plurality of shelf boards 6.

  As shown in FIG. 1, three door pockets 7 are fixed to the left door 4 and the right door 5 at intervals in the vertical direction. These six door pockets 7 are transparent in which food is stored, and the three door pockets 7 of the left door 4 are stored in the refrigerator compartment 2 with the left door 4 closed, and the three door pockets 7 of the right door 5 are stored. The door pocket 7 is stored in the refrigerator compartment 2 with the right door 5 closed.

  A chilled chamber 8 is formed in the refrigerator compartment 2 as shown in FIG. The chilled chamber 8 is open at the front and is disposed at the lowest part in the refrigerator compartment 2. In the chilled chamber 8, as shown in FIG. 1, two chilled containers 9 are arranged side by side in the left-right direction. These two chilled containers 9 are transparent containers for storing food, and are slidable in the front-rear direction between a storage state stored in the chilled chamber 8 and a pulled-out state pulled forward from the chilled chamber 8. ing.

  In the refrigerator compartment 2, as shown in FIG. The upper cabinet lamp 10 is disposed on the upper surface of the refrigerator compartment 2, and includes a plurality of upper LEDs 11 arranged in the front-rear direction and a translucent lens 12 that covers the plurality of upper LEDs 11 from below. The plurality of upper LEDs 11 are made of white LEDs that project white light from the top to the bottom, and the inside of the refrigerator compartment 2 is illuminated from above according to the light emission of the plurality of upper LEDs 11. Each of the plurality of upper LEDs 11 corresponds to a light source, and the upper internal lamp 10 corresponds to an internal lamp.

  As shown in FIG. 3, a left interior lamp 13 is fixed in the refrigerator compartment 2. This left internal lamp 13 is disposed on the left side of the refrigerator compartment 2 and has a plurality of left LEDs 14 arranged in the front-rear direction and a translucent lens 15 that covers the plurality of left LEDs 14 from the right. The plurality of left LEDs 14 are white LEDs that project white light from left to right, and the inside of the refrigerator compartment 2 is illuminated from the left in response to the plurality of left LEDs 14 emitting light. Each of the plurality of left LEDs 14 corresponds to a light source, and the left internal lamp 13 corresponds to an internal lamp.

  As shown in FIG. 3, a right interior lamp 16 is fixed in the refrigerator compartment 2. This right internal lamp 16 is disposed on the right side surface of the refrigerator compartment 2, and has a plurality of right LEDs 17 arranged in the front-rear direction and a translucent lens 18 that covers the plurality of right LEDs 17 from the left. The plurality of right LEDs 17 are white LEDs that project white light from right to left, and the inside of the refrigerator compartment 2 is illuminated from the right in response to the plurality of right LEDs 17 emitting light. Each of the plurality of right LEDs 17 corresponds to a light source, and the right internal lamp 16 corresponds to an internal lamp.

  As shown in FIG. 3, a lower interior lamp 19 is fixed in the refrigerator compartment 2. The lower interior lamp 19 is disposed on the upper surface of the chilled chamber 8 and includes a plurality of lower LEDs 20 arranged in the front-rear direction and a translucent lens 21 that covers the plurality of lower LEDs 20 from below. The plurality of lower LEDs 20 are composed of white LEDs that project white light from the top to the bottom, and the inside of the chilled chamber 8 is illuminated from above according to the light emission of the plurality of lower LEDs 20. Each of the plurality of lower LEDs 20 corresponds to a light source, and the lower interior lamp 19 corresponds to an interior lamp.

  As shown in FIG. 2, the refrigerator 1 includes an operation control circuit 22 and an LED circuit 23. The operation control circuit 22 has a CPU, a ROM, and a RAM, and supplies cold air into the refrigerating chamber 2 in response to electrically controlling the drive source of the refrigeration cycle 3. The LED circuit 23 outputs a PWM signal for each of the plurality of upper LEDs 11, the plurality of left LEDs 14, the plurality of right LEDs 17, and the plurality of lower LEDs 20, and the operation control circuit 22 is an LED circuit 23. The duty ratio of the PWM signal is adjusted for each LED according to electrical control of the LED, and the upper interior light 10 and the left interior are adjusted according to adjustment of the PWM signal duty ratio for each LED. The brightness of each of the lamp 13, the right internal lamp 16, and the lower internal lamp 19 is controlled. The operation control circuit 22 corresponds to control means and storage means.

  The left door sensor 24 in FIG. 2 changes its electrical state depending on whether or not the left door 4 is closed, and the operation control circuit 22 operates in accordance with the electrical state of the left door sensor 24. It is determined whether the door 4 is closed. The electric state of the right door sensor 25 changes depending on whether or not the right door 5 is closed, and the operation control circuit 22 determines whether the right door 5 is in accordance with the electric state of the right door sensor 25. When it is determined whether or not both the left door 4 and the right door 5 are closed, the plurality of upper LEDs 11, the plurality of left LEDs 14, the plurality of right LEDs 17, and the plurality of lower LEDs 20 are turned off. State.

  Illuminance information is recorded in the RAM of the operation control circuit 22. The illuminance information defines the illuminance for each of the plurality of upper LEDs 11, the plurality of left LEDs 14, the plurality of right LEDs 17 and the plurality of lower LEDs 20, and the operation control circuit 22 When it is determined that at least one of the right doors 5 is not closed, the plurality of upper LEDs 11 to the plurality of lower LEDs 20 are turned on at an illuminance corresponding to the illuminance information of the RAM for each LED. An initial value Ixi is recorded in advance in the ROM of the operation control circuit 22 as the illuminance, and in the initial state, a plurality of upper LEDs 11 to a plurality of LEDs are set according to the fact that all the illuminances of the illuminance information in the RAM are set to the initial value Ixi. The lower LED 20 is in a light emitting state at an illuminance Ixi.

  The refrigerator 1 includes a communication control circuit 26 as shown in FIG. The communication control circuit 26 transmits / receives information to / from the operation control circuit 22 via wiring, and includes a CPU, a ROM, and a RAM. As shown in FIG. 4, the communication control circuit 26 is connected to an external communication line 28 including an Internet network via a router 27, and the router 27 and the communication line 28 are connected to an external information terminal 29. Send and receive information. The communication control circuit 26 corresponds to communication means.

  The information terminal 29 is carried by the owner of the refrigerator 1 and is composed of a smartphone or a tablet personal computer. As shown in FIG. 4, the information terminal 29 has a liquid crystal display 30, and a transparent touch panel is mounted on the surface of the liquid crystal display 30. The liquid crystal display 30 displays an imaging key image. When the imaging key image is touched via the touch panel, the imaging command is sent from the information terminal 29 to the communication control circuit 26 through the communication line 28. Is sent.

  As shown in FIG. 1, an imaging camera 31 is fixed to the right door 5, and the imaging camera 31 is connected to the communication control circuit 26 via wiring. The imaging camera 31 is disposed on the rear surface of the right door 5 in a closed state, and includes a lens and an image sensor. This imaging camera 31 captures an image P (see FIG. 6) in the refrigerator compartment 2 with the right door 5 closed, and the angle of view of the imaging camera 31 is when the right door 4 is closed. It is set in the left-right direction and the up-down direction in the refrigerator compartment 2. The imaging camera 31 corresponds to an imager.

  The communication control circuit 26 captures a color internal image P in response to the electrical control of the imaging camera 31, and acquires the imaging result of the internal image P from the imaging camera 31 as a color video signal. . The communication control circuit 26 sets the internal video data by compressing the video signal using an algorithm of a lossless compression format, and the setting result of the internal video data is sent through the router 27 and the communication line 28 to the server 32 (FIG. 4). Send it to The server 32 records the internal video data from the communication control circuit 26 in association with the information terminal 29, and the information terminal 29 acquires the internal video data from the server 32 through the communication line 28.

  The imaging process of FIG. 5 is started when the CPU of the communication control circuit 26 receives an imaging command from the information terminal 29. If the CPU starts the imaging process, is there door closing information in step S1? Judge whether or not. This door closing information is transmitted to the communication control circuit 26 when the operation control circuit 22 determines that both the left door 4 and the right door 5 are closed, and the CPU outputs the left door 4 and the right door. If at least one of 5 is not closed, it is determined in step S1 that there is no door closing information, and the process proceeds to step S2.

  When the CPU proceeds to step S <b> 2, it transmits an imaging impossible command to the information terminal 29 through the router 27 and the communication line 28. This information terminal 29 displays a message (cannot image !!!!) on the liquid crystal display 30 when it receives a non-imaging command, and when at least one of the left door 4 and the right door 5 is not closed. It becomes impossible to acquire the internal video P using the information terminal 29.

  In a state where both the left door 4 and the right door 5 are closed, the CPU determines that there is door closing information from the operation control circuit 22 in step S1, and transmits a lighting command to the operation control circuit 22 in step S3. When the lighting control command is received, the operation control circuit 22 detects illuminance information from the RAM. When the illuminance information is detected, the plurality of upper LEDs 11 to the plurality of lower LEDs 20 are changed for each LED. Turn on with illumination. That is, the inside of the refrigerator compartment 2 is illuminated with the illuminance corresponding to the illuminance information of the operation control circuit 22 when the image P is captured by the imaging camera 31, and the user opens the left door 4 or the right door 5. Even when it is opened, it is illuminated with the same brightness as when the internal image P is imaged according to the same illuminance information as when the internal image P is captured.

  When the CPU transmits a lighting command in step S3, the imaging camera 31 is driven in step S4 to image the inside of the refrigerator compartment 2. In step S5, the video signal from the imaging camera 31 is acquired. In step S6, the video signal acquisition result is compressed to set the internal video data. In step S7, the internal video data setting result is set to the server 32. Is transmitted through the communication line 28. When the server 32 receives the internal video data, the server 32 transmits the reception result of the internal video data to the corresponding information terminal 29. The information terminal 29 displays the confident liquid crystal display when the internal video data is received. The internal video P is displayed on the container 30 according to the reception result of the internal video data.

  FIG. 6 is an internal image P displayed on the liquid crystal display 30 of the information terminal 29. This internal image P is an image in the refrigerator compartment 2 acquired by the imaging camera 31, and is displayed in a vertically long rectangular window Wi imitating the wall surface of the refrigerator compartment 2. This internal image P is captured in a state in which the plurality of upper LEDs 11 to the plurality of lower LEDs 20 are lit with brightness according to the illuminance information of the operation control circuit 22, and the user images the internal image of the information terminal 29. By visually recognizing P, the current food storage state in the refrigerator compartment 2 can be confirmed while staying in the distance.

  As shown in FIG. 6, the liquid crystal display 30 displays an upper key image Ku, a left key image Kl, a right key image Kr, a lower key image Kd, a dark key image D, and a bright key image L. These upper key video Ku to bright key video L are displayed on the information terminal 29 in response to the server 32 transmitting image data prerecorded on the server 32 to the information terminal 29. It is displayed outside the internal image P.

  The upper key image Ku is displayed on the internal image P. The upper key image Ku has a plurality of LED patterns arranged in the left-right direction, and the number of LED patterns of the upper key image Ku is set to be the same as the number of the upper LEDs 11. The upper key image Ku is attached with a picture (F) corresponding to the front located at the left end, and a picture (R) corresponding to the rear located at the right end.

  The left key image Kl is displayed on the left of the internal image P. The left key image Kl has a plurality of LED patterns arranged in the vertical direction, and the number of LED patterns of the left key image Kl is set to be equal to the number of the left LEDs 14. The left key image Kl is attached with an image (F) corresponding to the front and located at the upper end, and an image (R) corresponding to the later and located at the lower end.

  The right key video Kr is displayed to the right of the internal video P. The right key image Kr has a plurality of LED patterns arranged in the vertical direction, and the number of LED patterns of the right key image Kr is set to be the same as the number of right LEDs 17. The right key image Kr is attached with a pattern (F) corresponding to the front and located at the upper end, and a pattern (R) corresponding to the rear and located at the lower end.

  The lower key video Kd is displayed below the internal video P. The lower key image Kd has a plurality of LED patterns arranged in the left-right direction, and the number of LED patterns of the lower key image Kd is set to be the same as the number of the lower LEDs 20. The lower key image Kd is attached with a picture (F) corresponding to the front located at the left end and a picture (R) corresponding to the rear located at the right end.

  The dark key image D is displayed below the lower key image Kd. When the dark key image D is touched via the touch panel of the liquid crystal display 30, a communication control circuit is connected from the information terminal 29 through the communication line 28. A dark command is transmitted to 26. The bright key image L is displayed to the right of the dark key image D. When the bright key image L is touched via the touch panel of the liquid crystal display 30, the communication control circuit is connected from the information terminal 29 through the communication line 28. A bright command is transmitted to 26. Each of the bright key image L and the dark key image D corresponds to a button.

  When the CPU transmits the setting result of the internal video data in step S7, the CPU transmits a turn-off command to the operation control circuit 22 in step S8. The operation control circuit 22 is configured to turn off the plurality of upper LEDs 11 to the plurality of lower LEDs 20 when the turn-off command is received. It is turned on only for the minimum time required for imaging.

  When the CPU transmits a turn-off command in step S8, it determines whether or not there is an LED designation command in step S9. This LED designation command is used when the Nth one of the plurality of LED images of the upper key image Ku is touched via the touch panel and the Nth image from the top of the plurality of LED images of the left key image Kl. When one is touched via the touch panel and when the Nth one from the top of the plurality of LED patterns of the right key image Kr is touched via the touch panel and when the plurality of LED patterns of the lower key image Kd are touched When the Nth one from the left is touched via the touch panel, it is transmitted from the information terminal 29 to the communication control circuit 26 through the communication line 28, and the CPU determines that there is no LED designation command in step S9. If YES in step S11, the process proceeds to step S11. If it is determined in step S9 that there is an LED designation command, the LED designation frame is determined in step S10. To record the soil itself of RAM the process proceeds to step S11.

  In step S11, the CPU determines whether there is a dark command or a bright command from the information terminal 29. If it is determined that there is a dark command or a bright command, illuminance information is detected from the RAM of the operation control circuit 22 in step S12, and it is determined whether an LED designation command is recorded in its own RAM in step S13. To do. If it is determined that the LED designation command is recorded in its own RAM, the process proceeds to illuminance information processing 1 in step S14. If it is determined that the LED designation command is not recorded, the illuminance information in step S15. Move to processing 2.

The illuminance information processing 1 changes the detection result of the illuminance information. This process is performed by changing the illuminance for only the LED corresponding to the LED designation command in the RAM among the plurality of upper LEDs 11, the plurality of left LEDs 14, the plurality of right LEDs 17, and the plurality of lower LEDs 20. When a command is received, the illuminance is changed to be darker by the unit amount ΔIx, and when a bright command is received, the illuminance is changed to be brighter by ΔIx. The following 1) to 4) indicate which LED illuminance is changed according to the LED designation command of the RAM, and when the illuminance information is changed, the CPU erases the LED designation command from the RAM.
1) When the LED designation command is for designating the Nth from the left of the plurality of LED patterns of the upper key image Ku, the illuminance corresponding to the Nth upper LED11 from the front is changed.
2) If the LED designation command is for designating the Nth from the top of the plurality of LED patterns of the left key image Kl, the illuminance corresponding to the Nth left LED 14 from the front is changed.
3) When the LED designation command is for designating the Nth from the top of the plurality of LED patterns of the right key image Kr, the illuminance corresponding to the Nth right LED 17 from the front is changed.
4) If the LED designation command is for designating the Nth from the left of the plurality of LED patterns of the lower key image Kd, the illuminance corresponding to the Nth lower LED 20 from the front is changed.

  The illuminance information processing 2 changes the detection result of the illuminance information. This process is performed by changing the illuminance for each of the plurality of upper LEDs 11, the plurality of left LEDs 14, the plurality of right LEDs 17, and the plurality of lower LEDs 20, and when a dark command is received. The illuminance is changed to be darker by ΔIx, and when a bright command is received, the illuminance is changed to be brighter by ΔIx.

  When the CPU changes the illuminance information in step S14 or S15, the CPU transmits the change result of the illuminance information to the operation control circuit 22 in step S16. When the operation control circuit 22 receives the change result of the illuminance information, the operation control circuit 22 rewrites the illuminance information of the confident RAM with the change result of the illuminance information. When the refrigerator compartment 2 is opened after the illuminance information is rewritten, The plurality of upper LEDs 11 to the plurality of lower LEDs 20 are turned on with the illuminance corresponding to the rewrite result of the illuminance information.

  When the CPU transmits the change result of the illuminance information in step S16, the CPU retransmits the lighting command to the operation control circuit 22 in step S3. When the operation control circuit 22 receives the lighting command again, the plurality of upper LEDs 11 to the plurality of lower LEDs 20 are turned on again as a result of rewriting the illuminance information, and the user operates the information terminal 29. When the illuminance information is changed, the inside of the refrigerator compartment 2 is illuminated again according to the result of rewriting the illuminance information.

  When the CPU retransmits the lighting command in step S3, the imaging camera 31 is driven in step S4 to image the inside of the refrigerator compartment 2 again, and the light-off command is again sent to the operation control circuit 22 in steps S8 through S5 to S7. Send. Therefore, when the user changes the illuminance information by operating the information terminal 29, the image is taken again while the inside of the refrigerator compartment 2 is illuminated with the result of rewriting the illuminance information, and the illumination state is changed to the information terminal 29. The internal video P is displayed.

According to the said Example 1, there exists the following effect.
Information that the communication control circuit 26 receives the brightness of the upper storage lamp 10, the left storage lamp 13, the right storage lamp 16, and the lower storage lamp 19 when the imaging camera 31 captures the image P in the storage Control was performed according to the content of the command from the terminal 29. Therefore, since the user can operate the information terminal 29 to set the lighting when the inside image P is picked up to a desired brightness, the food storage status can be easily viewed according to the user's preference. Can be confirmed.

  The operation control circuit 22 stores the content of the command from the information terminal 29 as illuminance information, and when the refrigerator compartment 2 is opened, each of the upper storage lamp 10 to the lower storage lamp 19 is stored as illuminance information. Therefore, when the user opens the refrigerator compartment 2, the interior of the refrigerator compartment 2 is illuminated with the desired brightness set by operating the information terminal 29.

  When the imaging camera 31 captures the internal video P, the brightness corresponding to the content of the command from the information terminal 29 among the plurality of upper LEDs 11 of the internal light 10 is changed to the content of the command from the information terminal 29. Controlled accordingly. Therefore, the user can change the brightness of a part of the refrigeration room 2 in the front-rear direction by operating the information terminal 29, so that a part of the refrigeration room 2 in the front-rear direction can be changed as the internal image P. What has changed brightness can be acquired. This effect is the same for the left internal lamp 13, the right internal lamp 16, and the lower internal lamp 19.

  Since the dark key image D and the bright key image L are displayed on the information terminal 29, the user can touch the dark key image D or the bright key image L indirectly with a simple operation. The brightness of 19 can be adjusted.

  Each of the plurality of upper LEDs 11, the plurality of left LEDs 14, the plurality of right LEDs 17, and the plurality of lower LEDs 20 is composed of a full color LED. This full-color LED is obtained by sealing three LEDs of red, green, and blue in one package, and the operation control circuit 22 controls the LED circuit 23 to control the emission colors of the plurality of upper LEDs 11 to the plurality of lower LEDs 20. Control for each LED.

  Luminescent color information is recorded in the RAM of the operation control circuit 22. The light emission color information defines the light emission color for each of the plurality of upper LEDs 11, the plurality of left LEDs 14, the plurality of right LEDs 17 and the plurality of lower LEDs 20, and the operation control circuit 22 has a left door. When it is determined that at least one of 4 and the right door 5 is not closed, the plurality of upper LEDs 11 to the plurality of lower LEDs 20 are made to emit light in a light emission color corresponding to the light emission color information of the RAM for each LED, and the left door When it is determined that both 4 and the right door 5 are closed, the plurality of upper LEDs 11 to the plurality of lower LEDs 20 are turned off. The initial color Ci is recorded in advance in the ROM of the operation control circuit 22, and in the initial state, all the emission colors of the emission color information of the RAM are set to the initial color Ci, so that a plurality of upper LEDs 11 to a plurality of lower colors are set. The LED 20 is in a light emitting state with the initial color Ci.

  The imaging process of FIG. 7 is performed by the CPU of the communication control circuit 26 in place of the imaging process of FIG. 5. The CPU transmits a lighting command to the operation control circuit 22 in step S3, and drives the imaging camera 31 in step S4. By doing so, the inside of the refrigerator compartment 2 is imaged. Then, through steps S5 and S6, the setting result of the internal video data is transmitted to the information terminal 29 in step S7, and a turn-off command is transmitted to the operation control circuit 22 in step S8.

  When the lighting control command 22 is received, the operation control circuit 22 detects the issuance color information from the RAM, and turns on the plurality of upper LEDs 11 to the plurality of lower LEDs 20 with the emission color of the emission color information for each LED. The inside of the refrigerator compartment 2 is imaged in a state in which the plurality of upper LEDs 11 to the plurality of lower LEDs 20 are lit in the emission color corresponding to the same emission color information as when the refrigerator compartment 2 is opened.

  8 is displayed on the liquid crystal display 30 of the information terminal 29 according to the setting result of the internal video data, and the colors according to the emission colors of the plurality of upper LEDs 11 to the plurality of lower LEDs 20 are displayed. have. The cold color key image C and the warm color key image W are displayed in place of the dark key image D and the bright key image L. When the cold color key image C is touched via the touch panel, the information terminal 29 communicates with the communication line. 28, the cool color command is transmitted to the communication control circuit 26, and when the warm color key image W is touched via the touch panel, the warm color command is transmitted from the information terminal 29 to the communication control circuit 26 through the communication line 28.

  When the CPU transmits a turn-off command in step S8, the CPU determines whether or not there is an LED designation command from the information terminal 29 in step S9. If it is determined that there is an LED designation command, the LED designation command is recorded in the RAM in step S10 and the process proceeds to step S21. If it is determined that there is no LED designation command, the process proceeds to step S21.

  In step S21, the CPU determines whether there is a cold color command or a warm color command from the information terminal 29. If it is determined that there is a cold color command or a warm color command, the issued color information is detected from the RAM of the operation control circuit 22 in step S22, and whether or not the LED designation command is recorded in its own RAM in step S23. to decide. If it is determined that the LED designation command is recorded in its own RAM, the process proceeds to the light emission color information processing 1 in step S24. If it is determined that the LED designation command is not recorded, the light emission in step S25. The process proceeds to color information processing 2.

  The light emission color information processing 1 changes the detection result of the light emission color information. When the detection result of the light emission color information is changed, the LED designation command is deleted from the RAM. This process is performed by changing the light emission color of the light emission color information for only the plurality of upper LEDs 11, the plurality of left LEDs 14, the plurality of right LEDs 17, and the plurality of lower LEDs 20 according to the LED designation command of the RAM. When a cold command is received, the emission color is changed to the cold side (blue white side) by one level, and when the warm color command is received, the emission color is changed to the warm side (orange) by one level. Color side).

  The light emission color information processing 2 is for changing the detection result of the light emission color information. This process is performed by changing the emission color of the emission color information for each of the plurality of upper LEDs 11, the plurality of left LEDs 14, the plurality of right LEDs 17, and the plurality of lower LEDs 20, and a cold color command is issued. When received, the emission color is changed to the cold color side by one level, and when the warm color command is received, the emission color is changed to the warm color side by one level.

  When the CPU changes the emission color information in step S24 or step S25, the CPU transmits the change result of the emission color information to the operation control circuit 22 in step S26. When the operation control circuit 22 receives the change result of the emission color information, the operation control circuit 22 rewrites the emission color information of the confident RAM with the change result of the emission color information, and the refrigerator 2 is opened after the emission color information is rewritten. In this case, the plurality of upper LEDs 11 to the plurality of lower LEDs 20 are turned on with the emission color corresponding to the rewriting result of the emission color information.

  When the CPU transmits the light emission color information change result in step S26, the CPU retransmits the lighting command to the operation control circuit 22 in step S3. When the lighting control command 22 is received again, the operation control circuit 22 turns on the plurality of upper LEDs 11 to the plurality of lower LEDs 20 again according to the result of rewriting the emission color information, and the user operates the information terminal 29. Thus, when the emission color information is changed, the inside of the refrigerator compartment 2 is illuminated again according to the result of rewriting the emission color information.

  When the CPU retransmits the lighting command in step S3, the imaging camera 31 is driven in step S4 to image the inside of the refrigerator compartment 2 again, and the light-off command is again sent to the operation control circuit 22 in steps S8 through S5 to S7. Send. Therefore, when the user changes the light emission color information by operating the information terminal 29, the image is taken again with the inside of the refrigerator compartment 2 illuminated with the result of rewriting the light emission color information. The changed internal image P is displayed.

According to the said Example 2, there exist the following effects.
Information that the communication control circuit 26 receives the emission colors of the upper storage lamp 10, the left storage lamp 13, the right storage lamp 16, and the lower storage lamp 19 when the imaging camera 31 captures the image P in the storage Control was performed according to the content of the command from the terminal 29. Accordingly, since the lighting when the internal image P is captured by the user operating the information terminal 29 can be set to a favorite color, the internal image P having a color that suits the user's preference is acquired. can do.

  The operation control circuit 22 stores the content of the command from the information terminal 29 as light emission color information, and when the refrigerator compartment 2 is opened, each of the upper storage lamp 10 to the lower storage lamp 19 is changed to the emission color information. Since the lighting state is set to the emission color corresponding to the stored result, the interior of the refrigerator compartment 2 is illuminated with the favorite emission color set by operating the information terminal 29 when the user opens the refrigerator compartment 2.

  When the imaging camera 31 captures the internal video P, the emission color is changed to the content of the command from the information terminal 29 for the plurality of upper LEDs 11 of the internal light 10 according to the content of the command from the information terminal 29. Controlled accordingly. Accordingly, since the user can change the emission color of a part of the refrigerating room 2 in the front-rear direction by operating the information terminal 29, it is possible to change the front-rear direction of the refrigerating room 2 as the internal image P. A device whose emission color is changed can be acquired. This effect is the same for the left internal lamp 13, the right internal lamp 16, and the lower internal lamp 19.

  Since the cold color key image C and the warm color key image W are displayed on the information terminal 29, the user can touch the cold color key image C or the warm color key image W indirectly with a simple operation. The 19 emission colors can be adjusted.

  The imaging process of FIG. 9 is performed by the CPU of the communication control circuit 26 in place of the imaging process of FIG. 7, and the CPU transmits a lighting command to the operation control circuit 22 in step S3, and proceeds to steps S4 to S11. . Illuminance information and emission color information are recorded in the RAM of the operation control circuit 22. When the operation control circuit 22 receives a lighting command, the operation control circuit 22 changes the plurality of upper LEDs 11 to the plurality of lower LEDs 20 for each LED. The lighting state is set by the illuminance of the emission color and illuminance information. That is, the inside of the refrigerator compartment 2 is imaged in a state where the plurality of upper LEDs 11 to the plurality of lower LEDs 20 are lit with the emission color of the emission color information and the illuminance of the illuminance information.

  FIG. 10 shows an in-compartment image P displayed on the liquid crystal display 30 of the information terminal 29 according to the setting result of the in-compartment image data. The in-compartment image P corresponds to the emission colors of the plurality of upper LEDs 11 to the plurality of lower LEDs 20. It has brightness according to the color and illuminance. A dark key image D, a bright key image L, a cold color key image C, and a warm color key image W are displayed on the liquid crystal display 30 together with the interior image P.

  When the CPU determines that there is a dark command or a bright command from the information terminal 29 in step S11, the CPU detects illuminance information from the RAM of the operation control circuit 22 in step S12, and proceeds to step S13. If it is determined that the LED designation command is recorded in its own RAM, the process returns to step S3 via steps S14 and S16. If it is determined that the LED designation command is not recorded, steps S15 and S16. After that, the process returns to step S3.

  If the CPU determines that neither a dark command nor a bright command is present in step S11, the CPU determines whether there is a cold color command or a warm color command from the information terminal 29 in step S21. If it is determined that there is a cold color command or a warm color command, the issuance color information is detected from the RAM of the operation control circuit 22 in step S22, and the process proceeds to step S23. If it is determined that the LED designation command is recorded in its own RAM, the process returns to step S3 via steps S24 and S26. If it is determined that the LED designation command is not recorded, steps S25 and S26 are performed. After that, the process returns to step S3.

  That is, when the dark key image D or the bright key image L of the information terminal 29 is operated, the illuminance of some or all of the plurality of upper LEDs 11 to the plurality of lower LEDs 20 is changed, and the refrigeration room 2 has illuminance. The in-compartment video P with the illuminance changed is displayed on the information terminal 29 in response to the image being captured again in the changed state. When the cold color key image C or the warm color key image W of the information terminal 29 is operated, some or all of the emission colors of the plurality of upper LEDs 11 to the plurality of lower LEDs 20 are changed, and the inside of the refrigerator compartment 2 emits light. The in-compartment image P in which the emission color is changed is displayed on the information terminal 29 in accordance with the imaging in the color change state. Therefore, when the user operates the information terminal 29 while viewing the internal video P, the internal video P according to his / her preference can be acquired.

  In the first and third embodiments, when the refrigerator compartment 2 is opened, the plurality of upper LEDs 11, the plurality of left LEDs 14, the plurality of right LEDs 17, and the plurality of lower LEDs 20 are irrelevant to the illuminance information of the operation control circuit 22. The light emission state may be set at a certain illuminance, and the light emission state may be set based on the illuminance information of the operation control circuit 22 when the imaging camera 31 captures the internal video P.

  In Examples 2 and 3, when the refrigerator compartment 2 is opened, the plurality of upper LEDs 11, the plurality of left LEDs 14, the plurality of right LEDs 17, and the plurality of lower LEDs 20 are irrelevant to the emission color information of the operation control circuit 22. When the imaging camera 31 captures the image P in the warehouse, the emission state may be set by the emission color information of the operation control circuit 22.

In the first to third embodiments, an image inside the refrigerator with the subject in the freezing room, the vegetable room, or the ice making room may be captured by the imaging camera 31.
Although several embodiments of the present invention have been described, these embodiments have been presented by way of example and are not intended to limit the scope of the invention. These novel embodiments can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the scope of the invention. These embodiments and modifications thereof are included in the scope and gist of the invention, and are included in the invention described in the claims and the equivalents thereof.

  1 is a refrigerator, 2 is a refrigerator compartment (storage room), 10 is an upper storage lamp (internal storage lamp), 11 is an upper LED (light source), 13 is a left internal lamp (interior storage lamp), and 14 is a left LED ( Light source), 16 is a right internal lamp (internal light), 17 is a right LED (light source), 19 is a lower internal lamp (internal light), 20 is a lower LED (light source), and 22 is an operation control circuit (control). Means 26, a communication control circuit (communication means), 29 an information terminal, and 31 an imaging camera (imaging device).

Claims (4)

An interior light that illuminates the storage room,
An image pick-up device for picking up an image inside the storage room which is an image in the storage room;
Control means for electrically controlling the interior lamp, and when the image pickup device captures an interior image, control means for turning on the interior lamp;
In response to transmitting the imaging result of the internal video by the imaging device to an external information terminal, the imaging result of the internal video is displayed on the information terminal, and a command is transmitted from the information terminal A communication means for receiving the command in the case,
The control means controls the emission color or brightness of the interior light when the imager captures an interior image according to the content of the command from the information terminal received by the communication means. Refrigerator. Comprising storage means for storing the contents of the command from the information terminal;
2. The control unit according to claim 1, wherein, when the storage chamber is opened, the interior lamp is turned on with an emission color or brightness corresponding to the storage content of the storage unit. Refrigerator. The interior lamp has a plurality of light sources different from each other in arrangement,
The control means controls the emission color or brightness of the plurality of light sources according to the content of the command from the information terminal according to the content of the command when the imaging device captures an image inside the cabinet. The refrigerator according to claim 1 or 2, wherein An interior light that illuminates the storage room,
An image pick-up device for picking up an image inside the storage room which is an image in the storage room;
Control means for electrically controlling the interior lamp, and when the image pickup device captures an interior image, control means for turning on the interior lamp;
A communication means for transmitting an imaging result of the internal video by the imaging device to the outside;
In response to receiving the imaging result of the internal video from the communication means, the imaging result of the internal video is displayed, comprising an information terminal capable of transmitting a command to the communication means,
The control means controls the emission color or brightness of the interior lamp when the imaging device captures an interior image according to the content of the command from the information terminal received by the communication means. ,
The information terminal has a button for adjusting the emission color or brightness of the interior light, and transmits the command in response to the operation of the button. .

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