JP2016023910A - refrigerator - Google Patents

Abstract

PROBLEM TO BE SOLVED: To prevent wiring from getting damaged with the opening/closing of a door.SOLUTION: A refrigerator has a power transmission coil provided on a storage chamber side, a power receiving coil that is provided on a door side and receives power by radio from the power transmission coil, an electrical component that is provided on the door side and is supplied with power from the power transmission coil through the power receiving coil, and communication means that is provided on the door side, performs radio communication with the storage chamber side, and is supplied with power from the power transmission coil through the power receiving coil.SELECTED DRAWING: Figure 4

Description

  The examples relate to refrigerators.

  Some refrigerators have doors with electrical components. This door opens and closes the storage room, and power is supplied to the electrical components of the door from the storage room side through wiring.

JP 2006-336969 A Japanese Patent Laid-Open No. 2007-113858

  In the case of a conventional refrigerator, there is a possibility that wiring is damaged by repeatedly opening and closing the door.

  The refrigerator of the embodiment includes a door that opens and closes a storage room, a power transmission coil provided on the storage room side, a power reception coil that is provided on the door side and wirelessly receives power from the power transmission coil, and on the door side An electrical component provided and fed from the power transmission coil through the power reception coil and wireless communication between the electrical component provided on the door side and the storage chamber side, and fed from the power transmission coil through the power reception coil Communication means are provided.

The figure which shows Example 1 (sectional drawing which shows the internal structure of a refrigerator) Diagram showing signal path on cabinet side Diagram showing the power path on the cabinet side Sectional view showing the internal structure of the right door Diagram showing the power path on the door side Diagram showing the signal path on the door side Diagram showing the relationship between LED and photocoupler FIG. 7 equivalent diagram showing the second embodiment. FIG. 4 equivalent view showing Example 3

  The cabinet 1 of FIG. 1 has an open front, and has a vertically long rectangular shape when viewed from the front. This cabinet 1 is configured by housing a heat insulating material 4 between an outer box 2 and an inner box 3 and corresponds to a box. An upper partition plate 5 is fixed in the cabinet 1, and a refrigerator compartment 6 is formed on the upper partition plate 5. The refrigerator compartment 6 has an open front and corresponds to a storage compartment. An R temperature sensor 7 (see FIG. 2) is fixed in the refrigerator compartment 6, and the R temperature sensor 7 outputs an R temperature signal corresponding to the temperature in the refrigerator compartment 6.

  As shown in FIG. 1, a heat insulating partition plate 8 is fixed in the cabinet 1. The heat insulating partition plate 8 is disposed below the upper partition plate 5, and a vegetable compartment 9 is formed in the cabinet 1 between the upper partition plate 5 and the heat insulating partition plate 8. The vegetable room 9 has an open front and corresponds to a storage room.

  A lower partition plate 10 is fixed in the cabinet 1 as shown in FIG. The lower partition plate 10 is disposed below the heat insulating partition plate 8, and an ice making chamber 11 is formed in the cabinet 1 between the heat insulating partition plate 8 and the lower partition plate 10. A freezer compartment 12 is formed below. The ice making room 11 and the freezing room 12 are open at the front and correspond to a storage room. An F temperature sensor 13 (see FIG. 2) is fixed in the freezer compartment 12, and the F temperature sensor 13 outputs an F temperature signal corresponding to the temperature in the freezer compartment 12.

  As shown in FIG. 1, the cabinet 1 is provided with an R door 14 located in front of the refrigerator compartment 6. The R door 14 is rotatable about a vertical axis at the right end, and covers the front surface of the refrigerator compartment 6 from the front in a closed state. A gasket 15 is fixed to the R door 14 on the rear surface in the closed state. The gasket 15 has a frame shape that circulates around the outer peripheral portion of the R door 14, and the front surface of the refrigerating chamber 6 is hermetically sealed by the gasket 15 being in close contact with the front end surface of the cabinet 1 while the R door 14 is closed. Closed to state. The R door 14 corresponds to a door.

  As shown in FIG. 1, the cabinet 1 is provided with a V door 16 located in front of the vegetable compartment 9, and the V door 16 is compared with a closed state and a closed state that cover the front of the vegetable compartment 9 from the front. It can be moved back and forth between the previous open states. A gasket 17 is fixed to the rear surface of the V door 16, and the front of the vegetable compartment 9 is closed in an airtight state when the V door 16 is closed and the gasket 17 is in close contact with the front end surface of the cabinet 1 from the front. . The V door 16 corresponds to a door.

  As shown in FIG. 1, the cabinet 1 is provided with an I door 18 positioned in front of the ice making chamber 11. The I door 18 is compared with a closed state and a closed state in which the front surface of the ice making chamber 11 is covered from the front. It can be moved back and forth between the previous open states. A gasket 19 is fixed to the rear surface of the I door 18, and the front surface of the ice making chamber 11 is closed in an airtight state when the I door 18 is closed and the gasket 19 is in close contact with the front end surface of the cabinet 1 from the front. . The I door 18 corresponds to a door.

  As shown in FIG. 1, the cabinet 1 is provided with an F door 20 positioned in front of the freezer compartment 12, and the F door 20 is compared with a closed state and a closed state in which the front surface of the freezer compartment 12 is covered from the front. It can be moved back and forth between the previous open states. A gasket 21 is fixed to the rear surface of the F door 20, and the front surface of the freezer compartment 12 is closed in an airtight state when the F door 20 is closed and the gasket 21 is in close contact with the front end surface of the cabinet 1 from the front. . The F door 20 corresponds to a door.

  As shown in FIG. 1, a machine room 22 is formed in the cabinet 1. A compressor 23 of the refrigeration cycle is fixed in the machine room 22, and a condenser 24 is connected to the discharge port of the compressor 23. The capacitor 24 is disposed in the machine room 22, and an R evaporator 25 and an F evaporator 26 are connected to the capacitor 24. The R evaporator 25 is disposed after the refrigerator compartment 6, and the F evaporator 26 is disposed after the freezer compartment 12. The R evaporator 25 and the F evaporator 26 are connected to the suction port of the compressor 23, and refrigerant is supplied to the R evaporator 25 and the F evaporator 26 from the discharge port of the compressor 23 through the condenser 24.

  After the vegetable compartment 9, an R fan device 27 is fixed as shown in FIG. The R fan device 27 has a fan connected to a rotating shaft of a motor. Cold air is supplied from the R fan device 27 through the R evaporator 25 into the refrigeration chamber 6, and the refrigeration chamber 6 is introduced into the vegetable compartment 9. Cold air is supplied via. An F fan device 28 is fixed after the ice making chamber 12. The F fan device 28 has a fan connected to a rotating shaft of a motor, and cold air is supplied from the F fan device 28 to the ice making chamber 11 and the freezing chamber 12 through the F evaporator 26.

  The operation control circuit 29 in FIG. 2 is housed in the cabinet 1 and includes a CPU, a ROM, and a RAM. The operation control circuit 29 detects the R temperature signal from the R temperature sensor 7 and the F temperature signal from the F temperature sensor 13, and the detection result of the R temperature signal and the detection result of the F temperature signal are different from each other. The compressor 23, the R fan device 27, and the F fan device 28 are electrically controlled so as to converge to the target value.

  The power supply circuit 30 in FIG. 3 is housed in the cabinet 1. The power supply circuit 30 is connected to a commercial AC power supply 31 via a power supply line. In response to rectification and smoothing of the commercial AC power supply 31, the R temperature sensor 7, the F temperature sensor 13, the compressor 23, and the R fan. Drive power sources for the device 27, the F fan device 28, and the operation control circuit 29 are generated.

  As shown in FIG. 1, a coil box 32 is fixed to the ceiling wall of the refrigerator compartment 6 at the front end. The coil box 32 is disposed in the refrigerating chamber 6 and is sealed in an airtight state so that cold air cannot enter. As shown in FIG. 3, the coil box 32 houses an R power transmission coil 33, and the R power transmission coil 33 is connected to a power transmission circuit 34 via a power line. The power transmission side circuit 34 is mounted on a substrate and is housed in the cabinet 1. The power transmission circuit 34 is composed of a plurality of switching elements, and is connected to the power supply circuit 30 via a power supply line. In this power transmission side circuit 34, the operation control circuit 29 performs switching control according to the switching pattern of the ROM, and the operation control circuit 29 applies AC power to the R power transmission coil 33 by performing switching control of the power transmission side circuit 34. . The R power transmission coil 33 corresponds to a power transmission coil.

  FIG. 4 shows the R door 14, and the detailed configuration of the R door 14 is as follows. The door container 35 is open at the front and has a rear plate, an upper plate, a lower plate, a left plate, and a right plate. The door container 35 has a vertically long rectangular shape as viewed from the front, and the gasket 15 of the R door 14 is fixed to the rear plate of the door container 35. In this door container 35, a decorative plate 36, a front heater 37, a heat insulating material 38, and a rear heater 39 are accommodated in order from the front to the rear.

  The decorative plate 36 is made of a vertical glass plate, and the front surface of the door container 35 is closed by the decorative plate 36. A panel 40 is fixed to the decorative plate 36, and an outside air temperature sensor 41, an outside air humidity sensor 42, and an operation switch 43 (see FIG. 5) are fixed to the panel 40. The outside air temperature sensor 41 outputs an outside air temperature signal according to the outside air temperature, and the outside air humidity sensor 42 outputs an outside air humidity signal according to the humidity of the outside air. The operation switch 43 is operable by the user, and the electrical state changes according to the operation. Each of the outside air temperature sensor 41, the outside air humidity sensor 42, and the operation switch 43 corresponds to an electrical component, and each of the outside air temperature sensor 41 and the outside air humidity sensor 42 corresponds to a sensor.

  The front heater 37 is composed of a rectangular planar heater as viewed from the front. The front heater 37 is configured by sandwiching a heating element between two insulators, and is a vertical plate that contacts the upper plate, the lower plate, the left plate, the right plate, and the decorative plate 36 of the door container 35. It has a shape. The front heater 37 directly heats the decorative plate 36 and prevents the condensation on the front surface of the decorative plate 36 by heating the decorative plate 36. The front heater 37 corresponds to an electrical component and a heater.

  The heat insulating material 38 is made of urethane and is disposed between the front heater 37 and the rear heater 39. After this, the heater 39 is composed of a rectangular planar heater as viewed from the front, and has a vertical plate shape that contacts the rear plate, the upper plate, the lower plate, the left plate, and the right plate of the door container 35. . Thereafter, the heater 39 indirectly heats the gasket 15 of the R door 14 via the rear plate to the right plate of the door container 35, and heating the gasket 15 causes condensation on the surface of the gasket 15. To prevent. Thereafter, the heater 39 corresponds to an electrical component and a heater.

  As shown in FIG. 4, an electrical component box 44 is fixed to the rear plate of the door container 35 at the upper end portion. The electrical component box 44 is housed in the refrigerator compartment 6 with the R door 14 closed, and is closed in an airtight state so that cold air cannot enter. An R power receiving coil 45 is accommodated in the electrical component box 44, and the R power receiving coil 45 faces the R power transmitting coil 33 through a gap from the front when the R door 14 is closed. The R power receiving coil 45 is magnetically disconnected from the R power transmission coil 33 when the R door 14 is not closed, and is magnetically coupled to the R power transmission coil 31 when the R door 14 is closed. AC power is induced in the state of being coupled to. The R power receiving coil 45 corresponds to a power receiving coil.

  As shown in FIG. 5, a power receiving side circuit 46 is embedded in the heat insulating material 38. The power receiving side circuit 46 includes a rectifying unit 47 and a secondary battery 48. The rectifying unit 47 converts AC power induced by the R power receiving coil 45 into DC power, and the secondary battery 48 is supplied from the rectifying unit 47. To store DC power. The secondary battery 48 is connected to the front heater 37, the rear heater 39, the outside air temperature sensor 41, the outside air humidity sensor 42, and the operation switch 43 through a power line. DC drive power is supplied from 48.

  As shown in FIG. 5, an R door side control circuit 49 is embedded in the heat insulating material 38, and the R door side control circuit 49 is connected to the secondary battery 48 through a power line. The R door side control circuit 49 is supplied with DC drive power from the secondary battery 48, and has a CPU, a ROM, and a RAM as shown in FIG. The R door side control circuit 49 electrically controls the front heater 37 and the rear heater 39, and the outside air temperature signal from the outside air temperature sensor 41, the outside air humidity signal from the outside air humidity sensor 42, and the operation of the operation switch 43. Detect content. The operation switch 43 is for the user to specify the type of the cooling mode, and the R door side control circuit 49 sets the type of the cooling mode according to the detection result of the operation content of the operation switch 43.

  As shown in FIG. 7A, the door container 35 is formed with a recess 50 located at the upper end. The recess 50 has a rear surface that is open when the R door 14 is closed, and is disposed inside the gasket 15. A door-side LED 51 is fixed in the recess 50. The door-side LED 51 projects light from the front to the rear in the closed state of the R door 14, and is connected to the secondary battery 48 through a power line as shown in FIG. The door-side LED 51 is supplied with a DC driving power from the secondary battery 48. As shown in FIG. 6, the R-door-side control circuit 49 electrically controls the door-side LED 51, thereby allowing the outside air temperature signal. , The detection result of the outside air humidity signal, and the setting result of the cooling mode are transmitted from the door-side LED 51 by light.

  A recess 52 is formed in the ceiling wall of the refrigerator compartment 6 as shown in FIG. The front surface of the concave portion 52 is open, and the concave portion 50 of the R door 14 faces the concave portion 52 of the refrigerating chamber 6 from the front when the R door 14 is closed. A photocoupler 53 is fixed in the recess 52 of the refrigerator compartment 6. As shown in FIG. 3, the photocoupler 53 is connected to the power supply circuit 30 via a power supply line, and a DC driving power is applied from the power supply circuit 30. The photocoupler 53 receives an outside air temperature signal, an outside air humidity signal, and a cooling mode from the door-side LED 51, and the operation control circuit 29 receives an outside air temperature signal and an outside air humidity signal from the photocoupler 53 as shown in FIG. The light reception results in the cooling mode and the cooling mode are detected, and the compressor 23, the R fan device 27, and the F fan device 28 are controlled in accordance with the detection results in the cooling mode, so that the inside of the refrigerator compartment 6 and the inside of the freezing chamber 12 are in the cooling mode. Cool in a manner according to the setting result.

  A recess 54 is formed in the ceiling wall of the refrigerator compartment 6 as shown in FIG. The concave portion 54 has an opening on the front surface, and is disposed at a distance from the concave portion 52 in the left-right direction. An LED 55 is fixed in the recess 54. As shown in FIG. 3, the LED 55 is connected to the power supply circuit 30 via a power supply line, and a DC driving power is applied from the power supply circuit 30. The LED 55 projects light from the back to the front. As shown in FIG. 2, the operation control circuit 29 electrically controls the LED 55, thereby detecting the detection result of the R temperature signal of the R temperature sensor 7 from the LED 55. Send by light.

  As shown in FIG. 7B, the door container 35 has a recess 56 formed therein. The rear surface of the concave portion 56 opens when the R door 14 is closed, and faces the concave portion 54 of the refrigerator compartment 6 from the front when the R door 14 is closed. A door-side photocoupler 57 is fixed in the recess 56 of the R door 14. As shown in FIG. 5, the door-side photocoupler 57 is connected to the secondary battery 48 through a power line, and a DC driving power is applied from the secondary battery 48. The door-side photocoupler 57 receives the R temperature signal from the LED 55, and as shown in FIG. 6, the R-door-side control circuit 49 detects the light reception result of the R temperature signal from the door-side photocoupler 57, By controlling each of the front heater 35 and the rear heater 37 in accordance with the detection result of the R temperature signal, the detection result of the outside air temperature signal, and the detection result of the outside air humidity signal, it is possible to prevent dew condensation on the gasket 15 and the decorative plate 36. To do. The door-side photocoupler 57, the door-side LED 51, and the R-door-side control circuit 49 correspond to communication means.

  As shown in FIG. 1, a coil box 32 is fixed to the upper partition plate 5 at the front end. The coil box 32 is disposed in the vegetable compartment 9, and a V power transmission coil 58 is accommodated in the coil box 32 of the vegetable compartment 9 as shown in FIG. 3. The V power transmission coil 58 is connected to the power transmission side circuit 34 via a power line, and AC power is applied to the V power transmission coil 58 from the power transmission side circuit 34. The V power transmission coil 58 corresponds to a power transmission coil.

  The V door 16 of the vegetable compartment 9 is configured by housing a decorative plate 36, a front heater 37, a heat insulating material 38, and a rear heater 39 in a door container 35. A panel 40, a door side LED 51, and a door side photocoupler 57 are provided. It has the same mechanical configuration as the R door 14 except that it is not provided. An electrical component box 44 is fixed to the V door 16 as shown in FIG. 1, and a V power receiving coil 59 is housed in the electrical component box 44 of the V door 16 as shown in FIG. Yes. The V power receiving coil 59 is magnetically coupled to the V power transmission coil 58 when the V door 16 is closed, and is magnetically disconnected from the V power transmission coil 58 when the V door 16 is not closed. The V power receiving coil 59 corresponds to a power receiving coil.

  A power receiving side circuit 46 is embedded in the heat insulating material 38 of the V door 16, and the power receiving side circuit 46 of the V door 16 is connected to the V power receiving coil 59 through a power line. The power receiving side circuit 46 of the V door 16 is connected to the front heater 37 and the rear heater 39 of the V door 16 via a power line, and the front heater 37 and the rear heater 39 of the V door 16 are connected to the V transmission coil 58. A DC driving power is supplied in a non-contact manner through the V power receiving coil 59 and the power receiving side circuit 46 of the V door 16.

  A V door side control circuit is embedded in the heat insulating material 38 of the V door 16, and the V door side control circuit is connected to the power receiving side circuit 46 of the V door 16 via a power line. In this V door side control circuit, a DC driving power is supplied in a non-contact manner from the V power transmission coil 58 through the V power reception coil 59 and the power reception side circuit 46 of the V door 16, and in addition to the CPU, ROM and RAM, wireless It has a LAN function.

  The operation control circuit 29 has a wireless LAN function, and the detection result of the R temperature signal from the R temperature sensor 7, the detection result of the F temperature signal from the F temperature sensor 13, and the detection of the outside air temperature signal from the photocoupler 53. The result and the detection result of the outside humidity signal from the photocoupler 53 are wirelessly transmitted to the V door side control circuit. The V door side control circuit wirelessly receives the transmission result of the R temperature signal to the outside air humidity signal, and the front heater 37 and the rear heater 39 of the V door 16 receive the R temperature signal, the outside air temperature signal, and the outside air humidity signal. By controlling according to the reception result, it is possible to prevent dew condensation on the decorative plate 36 and the gasket 17 of the V door 16. This V door side control circuit corresponds to a communication means.

  As shown in FIG. 1, a coil box 32 is fixed to the heat insulating partition plate 8 at the front end. The coil box 32 is disposed in the ice making chamber 11, and an I power transmission coil 60 is accommodated in the coil box 32 of the ice making chamber 11 as shown in FIG. 3. The I power transmission coil 60 is connected to the power transmission side circuit 34 via a power line, and AC power is applied to the I power transmission coil 60 from the power transmission side circuit 34. The I power transmission coil 60 corresponds to a power transmission coil.

  The I door 18 of the ice making room 11 is configured by housing a decorative plate 36, a front heater 37, a heat insulating material 38, and a rear heater 39 in a door container 35, and a panel 40, a door side LED 51, and a door side photocoupler 57. It has the same mechanical configuration as the R door 14 except that it is not provided. As shown in FIG. 1, an electrical component box 44 is fixed to the I door 18. As shown in FIG. 3, an I power receiving coil 61 is accommodated in the electrical component box 44 of the I door 18. Yes. The I power receiving coil 61 is magnetically coupled to the I power transmission coil 60 when the I door 18 is closed, and is magnetically disconnected from the I power transmission coil 60 when the I door 18 is not closed. The I power receiving coil 61 corresponds to a power receiving coil.

  A power receiving side circuit 46 is embedded in the heat insulating material 38 of the I door 18, and the power receiving side circuit 46 of the I door 18 is connected to the I power receiving coil 61 via a power line. The power receiving side circuit 46 of the I door 18 is connected to the front heater 37 and the rear heater 39 of the I door 18 through a power line, and the front heater 37 and the rear heater 39 of the I door 18 are connected to the I power transmission coil 60. A DC driving power is supplied in a non-contact manner through the I power receiving coil 61 and the power receiving side circuit 46 of the I door 18.

  An I door side control circuit is embedded in the heat insulating material 38 of the I door 18, and the I door side control circuit is connected to the power receiving side circuit 46 of the I door 18 via a power line. In this I door side control circuit, DC driving power is supplied from the I power transmission coil 60 through the I power receiving coil 61 and the power receiving side circuit 46 of the I door 18 in a non-contact manner. It has a LAN function. The I door side control circuit wirelessly receives the transmission result of the R temperature signal to the outside air humidity signal from the operation control circuit 29. The front heater 37 and the rear heater 39 of the I door 18 are connected to the F temperature signal and the outside air temperature. By controlling according to the reception result of the signal and the outside air humidity signal, it is possible to prevent dew condensation on the decorative plate 36 and the gasket 19 of the I door 18. This I door side control circuit corresponds to a communication means.

  As shown in FIG. 1, a coil box 32 is fixed to the lower partition plate 10 at the front end. The coil box 32 is disposed in the freezer compartment 12, and an F power transmission coil 62 is accommodated in the coil box 32 of the freezer compartment 12 as shown in FIG. 3. The F power transmission coil 62 is connected to the power transmission side circuit 34 via a power line, and AC power is applied to the F power transmission coil 62 from the power transmission side circuit 34. The F power transmission coil 62 corresponds to a power transmission coil.

  The F door 20 of the freezer compartment 12 includes a decorative plate 36, a front heater 37, a heat insulating material 38, and a rear heater 39 in a door container 35, and a panel 40, a door side LED 51, and a door side photocoupler 57. It has the same mechanical configuration as the R door 14 except that it is not provided. An electrical component box 44 is fixed to the F door 20 as shown in FIG. 1, and an F power receiving coil 63 is accommodated in the electrical component box 44 of the F door 20 as shown in FIG. Yes. The F power receiving coil 63 is magnetically coupled to the F power transmission coil 62 when the F door 20 is closed, and is magnetically disconnected from the F power transmission coil 62 when the F door 20 is not closed. The F power receiving coil 63 corresponds to a power receiving coil.

  A power receiving side circuit 46 is embedded in the heat insulating material 38 of the F door 20, and the power receiving side circuit 46 of the F door 20 is connected to the F power receiving coil 63 through a power line. The power receiving side circuit 46 of the F door 20 is connected to the front heater 37 and the rear heater 39 of the F door 20 through a power line, and the front heater 37 and the rear heater 39 of the F door 20 are connected to the F power transmission coil 62. A DC driving power is supplied in a non-contact manner through the F power receiving coil 63 and the power receiving side circuit 46 of the F door 18.

  An F door side control circuit is embedded in the heat insulating material 38 of the F door 20, and the F door side control circuit is connected to the power receiving side circuit 46 of the F door 20 via a power line. In this F door side control circuit, a DC driving power is supplied in a non-contact manner from the F power transmission coil 62 through the F power reception coil 63 and the power reception side circuit 46 of the F door 20, and wirelessly in addition to the CPU, ROM and RAM. It has a LAN function. The F door side control circuit wirelessly receives the transmission result of the R temperature signal to the outside air humidity signal from the operation control circuit 29. The front heater 37 and the rear heater 39 of the F door 20 are connected to the F temperature signal and the outside air temperature. By controlling according to the reception result of the signal and the outside air humidity signal, it is possible to prevent condensation on the decorative plate 36 and the gasket 21 of the F door 18. This F door side control circuit corresponds to a communication means.

According to the said Example 1, there exists the following effect.
Because the front heater 37, the rear heater 39, the outside heater 39, the outside air temperature sensor 41, the outside air humidity sensor 42, and the operation switch 43 of the R door 14 are wirelessly fed from the R power transmission coil 33 on the refrigerator compartment 6 side through the R power reception coil 45 on the R door 14 side. The wiring for supplying power to the front heater 37 to the operation switch 43 from the refrigerator compartment 6 side becomes unnecessary. In addition, since information is wirelessly communicated between the refrigerator compartment 6 side and the R door 14 side, wiring for communicating information is not necessary. Further, wireless power is supplied to the R-door control circuit 49, the door-side LED 51, and the door-side photocoupler 57 for wireless communication from the R power transmission coil 33 on the refrigerator compartment 6 side through the R power reception coil 45 on the R door 14 side. Wiring for supplying power to the means is also unnecessary. Accordingly, since the wiring between the refrigerator compartment 6 side and the R door 14 side is abolished, there is no possibility that the wiring is damaged in accordance with repeated opening and closing of the R door 14. This effect is the same for the V door 16, the I door 18 and the F door 20.

  Since the wireless power is supplied to the front heater 37 and the rear heater 39 of the R door 14 from the refrigerator compartment 6 side, it is possible to prevent condensation on the R door 14. In particular, in the case of the V door 16, the I door 18 and the F door 20, it is possible to prevent dew condensation from occurring even though the wiring is difficult due to the drawer type.

  Since the information for controlling the front heater 37 and the rear heater 39 of the R door 14 is wirelessly communicated between the refrigerator compartment 6 side and the R door 14 side, the front heater 37 and the rear heater 39 of the R door 14 are finely controlled. Is possible. This effect is the same for the V door 16, the I door 18 and the F door 20.

  Wireless power was supplied to the outside temperature sensor 41 and the outside humidity sensor 42 of the R door 14 from the refrigerator compartment 6 side. Therefore, since the front heater 37 and the rear heater 39 of the R door 14 can be controlled according to external information, it is possible to reliably prevent condensation on the R door 14 with less power consumption.

  Since the R power transmission coil 33 is disposed at the front end portion of the cabinet 1, the distance between the R power reception coil 45 and the R power transmission coil 33 when the R door 14 is closed is shortened. Therefore, since the degree of magnetic coupling between the R power transmission coil 33 and the R power reception coil 45 in the closed state of the R door 14 is increased, power is efficiently transmitted from the R power transmission coil 33 to the R power reception coil 45. This effect is the same for the V door 16, the I door 18 and the F door 20.

  As shown in FIG. 8, the cord heater 71 is accommodated in the gasket 15 of the R door 14, and the rear heater 39 of the R door 14 is eliminated. The cord heater 71 is a linear heater covered with an insulating tube, and has a frame shape along the gasket 15. The cord heater 71 is wirelessly supplied with power from the R power transmission coil 33 through the R power reception coil 45, and the R door side control circuit 49 has an R temperature signal from the operation control circuit 29 and an outside air temperature signal from the outside air temperature sensor 41. By controlling the code heater 71 in accordance with the outside air humidity signal from the outside air humidity sensor 42, dew condensation on the surface of the gasket 15 is prevented. The cord heater 71 corresponds to an electrical component and a heater.

According to the said Example 2, there exist the following effects.
The cord heater 71 was accommodated in the gasket 15 of the R door 14, and the cord heater 71 was wirelessly supplied with power from the refrigerator compartment 6 side. Accordingly, since the gasket 15 is directly heated by the cord heater 71, it is possible to reliably prevent condensation from occurring on the surface of the gasket 15 with a small amount of power consumption.

  In the second embodiment, the cord heater 71 may be housed in the gasket 17 of the V door 16, the gasket 19 of the I door 18, or the gasket 21 of the F door 20.

  As shown in FIG. 9, the R door 14 is configured by housing a decorative plate 36 and a heat insulating material 38 in a door container 35, and the front heater 37 and the rear heater 39 are omitted. A heating plate 81 is accommodated in the door container 35. The heating plate 81 is made of an aluminum thin plate and is in contact with the rear surface of the decorative plate 36. The heating plate 81 is connected to the R power receiving coil 45 in the electrical component box 44 via a heating wire 82, and generates heat when heat is transmitted from the R power receiving coil 45 through the heating wire 82. The heating plate 81 heats the decorative plate 36 by generating heat. By heating the decorative plate 36, condensation on the front surface of the decorative plate 36 is prevented.

According to the said Example 3, there exist the following effects.
Since heat is transmitted from the R power receiving coil 45 to the front surface of the R door 14, it is possible to prevent condensation on the front surface of the R door 14 without using the electrical front heater 37.

In the third embodiment, the heating plate 81 may be housed in the door container 35 of the V door 16, the I door 18, or the F door 20.
In the third embodiment, the entire area of the decorative board 36 may be directly heated by the R electric power receiving coil 45 by causing the conductor of the R electric receiving coil 45 to be brought into contact with the entire area of the rear surface of the decorative board 36. The same applies to the V door 16, the I door 18 and the F door 20.

In the said Examples 1-3, you may perform the wireless communication between the R door 14 side and the cabinet 1 side by wireless LAN.
In the said Examples 1-3, you may perform the radio | wireless communication between the V door 16 side and the cabinet 1 side by light. The same applies to the I door 18 and the F door 20.

  In the first to third embodiments, wireless communication between the R door 14 side and the cabinet 1 side may be performed by magnetism. In this case, it is preferable to transmit and receive information using each of the R power transmission coil 33 and the R power reception coil 45. The same applies to the V door 16, the I door 18 and the F door 20.

  In the first to third embodiments, the R power receiving coil 45 is magnetically coupled to the R power transmitting coil 33 in both the closed state and the non-closed state of the R door 14, and both the closed state and the non-closed state of the R door 14 are obtained. Thus, power may be wirelessly transmitted from the R power transmission coil 33 to the R power reception coil 45. The same applies to the V door 16, the I door 18 and the F door 20.

  In the first to third embodiments, electric power may be transmitted in a non-contact manner from the cabinet 1 side to the R door 14 side, the V door 16 side, the I door 18 side, or the F door 20 side by a radio wave method or a resonance method.

  As mentioned above, although the Example of this invention was described, this Example is shown as an example and is not intending limiting the range of 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 cabinet (box), 6 is a refrigerator room (storage room), 9 is a vegetable room (storage room), 11 is an ice making room (storage room), 12 is a freezer room (storage room), 14 is an R door (door) ), 15 is a gasket, 16 is a V door (door), 17 is a gasket, 18 is an I door (door), 19 is a gasket, 20 is an F door (door), 21 is a gasket, 33 is an R power transmission coil (power transmission coil) ), 37 is a front heater (electric part, heater), 39 is a rear heater (electric part, heater), 41 is an outside air temperature sensor (electric part, sensor), 42 is an outside air humidity sensor (electric part, sensor), and 43 is Operation switch (electrical component), 45 is R power receiving coil (power receiving coil), 58 is V power transmitting coil (power transmitting coil), 59 is V power receiving coil (power receiving coil), 60 is I power transmitting coil (power transmitting coil), 61 is I Receiving coil (receiving coil), 62 is F power transmission Yl (power transmission coil), 63 F receiving coil (receiving coil), 71 is a code heater (electric parts, heater).

Claims (8)

A door for opening and closing the storage room;
A power transmission coil provided on the storage room side;
A power receiving coil that is provided on the door side and wirelessly receives power from the power transmitting coil;
An electrical component provided on the door side and fed from the power transmission coil through the power reception coil;
A refrigerator that is provided on the door side and performs wireless communication with the storage room side, and includes communication means that is fed from the power transmission coil through the power reception coil.   The refrigerator according to claim 1, wherein the electrical component is a heater that heats the door.   The refrigerator according to claim 1, wherein the communication unit wirelessly communicates information for controlling the electrical component.   The refrigerator according to any one of claims 1 to 3, wherein the communication unit wirelessly communicates with light, radio waves, or magnetism.   The refrigerator according to any one of claims 1 to 4, wherein a sensor for detecting information outside the storage room is provided as the electrical component on the door side.   The refrigerator according to any one of claims 1 to 5, wherein heat is transmitted from the power receiving coil to a front surface of the door.   The refrigerator according to any one of claims 1 to 6, wherein the door is provided with a gasket in which a heater as the electrical component is accommodated. A box having the storage chamber;
The refrigerator according to any one of claims 1 to 7, wherein the power transmission coil is disposed at a front end of the box.

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