JP2018054288A - refrigerator - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a refrigerator capable of reducing operational error at an operation unit for changing a setting relating to an operation.SOLUTION: A refrigerator 10 includes a heat insulating housing 11 having an opening, a door 33 for opening and closing the opening, a first operation unit 51 disposed on a front face of the door 33 and receiving an operation to change a setting relating to an operation of the refrigerator 10, an operation control portion switching a normal mode receiving the operation to the first operation unit 51 and a standby mode not receiving the operation to the first operation unit, and a second operation unit 52 disposed on the front face of the door 33 and receiving an operation for switching from the standby mode to the normal mode. The operation control portion switches the mode to the normal mode when the second operation unit 52 is operated during the standby mode.SELECTED DRAWING: Figure 1

Description

  Embodiments of the present invention relate to a refrigerator.

  Generally, a refrigerator is provided with an operation unit such as an operation panel in order to change settings related to operation in response to a user's request. The operation unit is often provided on the front surface of the refrigerator door from the viewpoint of operability and the like.

  However, such an operation unit may be erroneously operated by hitting the user's body, and thus may be erroneously changed to a setting not intended by the user.

JP 2012-78086 A

  Then, the refrigerator which can reduce an erroneous operation is provided about the operation part for changing the setting regarding a driving | operation.

  The refrigerator of the present embodiment includes a heat-insulating box having an opening, a door that opens and closes the opening, a first operation unit that is provided on the front surface of the door and receives an operation for changing settings related to operation of the refrigerator, An operation control unit that switches between a normal mode that accepts an operation on the first operation unit and a standby mode that does not accept an operation on the first operation unit, and an operation that is provided on the front surface of the door and switches from the standby mode to the normal mode And a second operation unit. The operation control unit switches to the normal mode when the second operation unit is operated during the standby mode.

The front view which shows the external appearance of the refrigerator by 1st embodiment The figure which shows typically the internal structure of a refrigerator, and the structure of a refrigerating cycle. 1 is a cross-sectional view of the operating device shown along line AA in FIG. Block diagram showing the control system Exploded perspective view of operating device Diagram showing configuration of operation area and display area Flow chart showing control contents of operation control unit in normal mode The flowchart which shows the control content of the operation control part in standby mode The enlarged view of the 2nd operation part by a second embodiment FIG. 9 equivalent diagram according to the third embodiment FIG. 5 equivalent diagram according to the fourth embodiment FIG. 5 equivalent diagram according to the fifth embodiment

  Hereinafter, refrigerators according to a plurality of embodiments will be described with reference to the drawings. In addition, in each embodiment, the same code | symbol is attached | subjected to the substantially same component, and description is abbreviate | omitted.

(First embodiment)
As shown in FIGS. 1 and 2, the refrigerator 10 includes a plurality of storage chambers in a heat insulating box 11 having a vertically long rectangular box shape whose front surface is open. Hereinafter, the opening side of the heat insulating box 11, that is, the left side in FIG. 2 will be described as the front side of the refrigerator 10.
As shown in FIG. 2, the heat insulating box 11 has a heat insulating material 113 between a steel plate outer box 111 and a synthetic resin inner box 112. The heat insulating material 113 is, for example, urethane foam or a vacuum heat insulating panel. Inside the heat insulation box 11, a refrigerator compartment 12 and a vegetable compartment 13 are provided in order from the upper stage, an ice making room 14 and an upper stage freezer room 15 are provided side by side on the lower side, and a lower stage freezer room 16 is further provided on the lower side. Is provided. The ice making chamber 14 is provided with an automatic ice making device (not shown).

  The refrigerator compartment 12 and the vegetable compartment 13 are both storage compartments in the refrigerated temperature zone, and the refrigerator compartment 12 and the vegetable compartment 13 are usually set at different temperatures. For example, the maintenance temperature of the refrigerator compartment 12 is set to 1 to 5 ° C, and the maintenance temperature of the vegetable compartment 13 is set to 2 to 6 ° C, which is slightly higher than that. The refrigerator compartment 12 and the vegetable compartment 13 are vertically partitioned by a plastic partition wall 17. In the refrigerator compartment 12, a storage compartment in a refrigerator temperature zone, in this case, a refrigerator compartment temperature sensor 18 for detecting the temperature in the refrigerator compartment 12 is provided. The refrigerator compartment temperature sensor 18 is composed of, for example, a thermistor.

  The ice making room 14, the upper freezer room 15, and the lower freezer room 16 are all storage rooms in a freezing temperature zone, for example, a minus temperature zone of −10 to −20 ° C. A space between the vegetable compartment 13, the ice making compartment 14 and the upper freezer compartment 15 is partitioned vertically by a heat insulating partition wall 19. In the lower freezer compartment 16, there is provided a freezer temperature zone storage chamber, in this case, a freezer compartment temperature sensor 20 for detecting the temperature in the lower freezer compartment 16. The freezer compartment temperature sensor 20 is composed of, for example, a thermistor.

  A refrigerator 10 shown in FIG. 2 is incorporated in the refrigerator 10. In FIG. 2, the refrigeration cycle 21 is schematically shown in a state where it is removed from the refrigerator 10. In the refrigeration cycle 21, a compressor 22, a condenser 23, a dryer 24, a switching valve 251, a refrigeration cooler 26, and a refrigeration cooler 27 are annularly connected in the order of refrigerant flow. The switching valve 251 is driven in response to a control command, and supplies the refrigerant pumped from the compressor 22 to either the refrigeration cooler 26 or the refrigeration cooler 27. A check valve 252 is provided between the refrigeration cooler 27 and the compressor 22. Although not shown in detail, the compressor 22 is disposed in a machine room formed in the upper rear portion or the upper rear portion of the refrigerator 10.

  The refrigeration cooler 26 is provided in a refrigeration duct 28 formed at the rear of the refrigeration room 12 and the vegetable room 13. The refrigeration duct 28 extends in the vertical direction along the rear wall surfaces of the refrigerator compartment 12 and the vegetable compartment 13, and has an air outlet 281 on the upper side and a suction port 282 on the lower side. A refrigeration blower 29 is provided in the refrigeration duct 28 on the suction port 282 side. When the refrigeration blower 29 is driven, the air in the vegetable compartment 13 is sucked into the refrigeration duct 28 from the suction port 282 by the blowing action of the refrigeration blower 29. The air sucked into the refrigeration duct 28 is cooled by the refrigeration cooler 26, and then supplied from the outlet 281 into the refrigeration chamber 12. And the cold air supplied in the refrigerator compartment 12 cools the refrigerator compartment 12 and the vegetable compartment 13, and is sucked into the refrigerator duct 28 from the suction port 282 again. In this way, the cold air generated by the refrigeration cooler 26 circulates through the refrigeration room 12, the vegetable room 13, and the refrigeration duct 28, whereby the refrigeration room 12 and the vegetable room 13 are cooled.

  The refrigeration cooler 27 is provided in a refrigeration duct 30 formed at the rear of the ice making chamber 14, the upper freezing chamber 15, and the lower freezing chamber 16. In addition, a defrost heater 32 that defrosts frost generated in the freezer cooler 27 is provided in the vicinity of the freezer cooler 27. The freezing duct 30 extends in the vertical direction along the rear wall surfaces of the ice making chamber 14, the upper freezing chamber 15, and the lower freezing chamber 16, and has an air outlet 301 on the upper side and a suction port 302 on the lower side. A refrigeration blower 31 is provided in the refrigeration duct 30 on the outlet 301 side. When the refrigeration blower 31 is driven, the air in the lower freezer compartment 16 is sucked into the refrigeration duct 30 from the suction port 302 by the blowing action of the refrigeration blower 31. The air sucked into the refrigeration duct 30 is cooled by the refrigeration cooler 27 and then supplied from the outlet 301 into the ice making chamber 14 and the upper freezing chamber 15. Then, the cool air supplied into the ice making chamber 14 and the upper freezing chamber 15 cools the ice making chamber 14, the upper freezing chamber 15, and the lower freezing chamber 16, and is sucked into the freezing duct 30 from the suction port 302 again. In this way, the cold air generated by the freezing cooler 27 circulates in the ice making chamber 14, the upper freezing chamber 15, the lower freezing chamber 16, and the freezing duct 30, whereby the ice making chamber 14, the upper freezing chamber 15, And the lower freezer compartment 16 is cooled.

As shown in FIG. 1, the refrigerator 10 includes a refrigerator compartment door 33, a vegetable compartment door 34, an ice making compartment door 35, an upper freezer compartment door 36, and a lower freezer compartment door 37. The refrigerating room door 33 corresponds to the refrigerating room 12, has hinge portions 38 on both the left and right sides of the heat insulating box 11, and is provided in a double door manner. The refrigerator compartment door 33 opens and closes the opening on the front side of the refrigerator compartment 12.
The vegetable compartment door 34, the ice making compartment door 35, the upper freezing compartment door 36, and the lower freezing compartment door 37 correspond to the vegetable compartment 13, the ice making compartment 14, the upper freezing compartment 15, and the lower freezing compartment 16, respectively. The vegetable compartment door 34, the ice making compartment door 35, the upper freezer compartment door 36, and the lower freezer compartment door 37 are each configured to be a drawer type. The vegetable compartment door 34, the ice making compartment door 35, the upper freezing compartment door 36, and the lower freezing compartment door 37 open and close the front openings of the vegetable compartment 13, the ice making compartment 14, the upper freezing compartment 15, and the lower freezing compartment 16, respectively. . The vegetable compartment door 34, the ice making compartment door 35, the upper freezer compartment door 36, and the lower freezer compartment door 37 are each provided with a storage case (not shown) on the back side.

The refrigerator compartment door 33, the vegetable compartment door 34, the ice making compartment door 35, the upper freezer compartment door 36, and the lower freezer compartment door 37 are shown in FIG. 40 and a heat insulating material 41 between them. The inner plate 39 is composed of a synthetic resin plate. The heat insulating material 41 is made of, for example, urethane foam or a vacuum heat insulating panel.
The outer plate 40 is made of a flat plate such as glass having translucency. In this case, the glass constituting the outer plate 40 includes organic glass made of synthetic resin. A light shielding layer 401 is provided on the inner surface of the outer plate 40, that is, the surface on the inner plate 39 side. The light shielding layer 401 is made of a light shielding material, that is, a material that reflects or absorbs light. In this case, the light shielding layer 401 is formed on the inner side surface of the outer plate 40 by attaching a sheet-like member made of a light shielding material or applying a paint. When the user looks at the outer plate 40 from the outside of the refrigerator 10, the gloss due to the translucency of the glass can be confirmed as the appearance of the outer plate 40. Further, the heat insulating material 41 provided inside the outer plate 40 is not visually recognized by the light shielding layer 401 from the outside.

  As shown in FIG. 4, the refrigerator 10 includes a main control device 42 and an operation device 50. The main control device 42 includes a microcomputer, a timer, a storage device, and the like (not shown). An operation device 50 is connected to the main control device 42 as an input / output device. The main controller 42 is connected to the refrigerator temperature sensor 18 and the freezer temperature sensor 20 as sensor devices. The refrigerator 29, the refrigerator 31 and the compressor 22 of the refrigeration cycle 21 and the switching valve are controlled. 251, a defrost heater 32, and the like are connected. The main control device 42 is based on detection signals from the refrigerator compartment temperature sensor 18 and the freezer compartment temperature sensor 20 and a control program stored in advance, and a refrigerator fan 29, a refrigerator fan 31, a compressor 22, and a switching valve 251. And the defrost heater 32 and the like are controlled.

  The main controller 42 has a plurality of operation modes related to power saving, for example, “power saving mode”, “outing mode”, “peak shift mode”, and the like. In this case, when the power saving mode is selected, the main controller 42 controls the compressor 22 and the like so that the temperature in each storage room does not affect the food, for example, 1 to 2 ° C. above the set temperature. Drive at a higher temperature. Thereby, it can drive | operate by power saving compared with the driving | running content set by the user.

  When the outing mode is selected, the main controller 42 operates in the power saving mode for about 3 hours after the outing mode is selected, for example. This is because the door is not opened and closed by the user while the user is out and the temperature in the storage chamber is stable. By selecting the outing mode before the user goes out, the user can drive with less power than normal operation while the user is out.

  When the peak shift mode is selected, the main controller 42 shifts the time zone in which the power consumption by the refrigerator 10 is maximum from a time zone in which power demand is tight to a slow time zone. In this case, the main control device 42 avoids the defrosting operation by the defrosting heater 32 with high power consumption or the ice making operation by the automatic ice making device, for example, during the daytime from 13:00 to 16:00 when the power demand peaks. The power demand is low, for example, from 1 to 4 at night. Thereby, the power consumption in the time zone corresponding to the peak of power demand can be suppressed, and it can contribute to avoiding large-scale power outages and planned power outages.

  The user operates the operation device 50 to set the temperature of each storage room, change the operation mode, and the like. The operating device 50 is incorporated in the refrigerator compartment door 33. The operating device 50 is configured as a so-called touch sensor type. As shown in FIGS. 1 and 6, the operation device 50 includes a part of the outer surface of the outer plate 40 of the refrigerator compartment door 33 as an operation area 402 and a display area 403.

  As shown in FIG. 6, the operation area 402 is provided with a plurality of first operation units 51 and second operation units 52. The first operation unit 51 and the second operation unit 52 are composed of characters and graphic parts indicating the object and contents of the operation. A plurality of display units 53 are provided in the display area 403. The display unit 53 includes characters and graphic parts that indicate the current setting contents of the refrigerator 10. When the first operation unit 51 and the display unit 53 are illuminated as necessary, the first operation unit 51 is displayed in the operation region 402 and the display unit 53 is displayed in the display region 403. The user sets the operation content of the refrigerator 10 by operating the first operation unit 51 and the second operation unit 52, and looks at the display unit 53 displayed in the display area 403, so that the current setting content etc. Confirm.

  Specifically, as shown in FIGS. 5 and 3, the operating device 50 includes a printing member 54, a capacitance sensor 55, and an apparatus main body 56. The printing member 54 is formed of a rectangular plate-like member and is provided in contact with the inner side of the outer plate 40. The printing member 54 includes a plurality of first operation unit printing units 541 corresponding to the first operation unit 51 and a plurality of display unit printing units 542 corresponding to the display unit 53. The first operation unit printing unit 541 is configured with characters and graphics corresponding to the first operation unit 51, and the display unit printing unit 542 is configured with characters and graphics corresponding to the display unit 53. In the printing member 54, the first operation unit printing unit 541 and the display unit printing unit 542 have translucency, and portions other than the first operation unit printing unit 541 and the display unit printing unit 542 have light shielding properties. Have. In this case, the printing member 54 performs so-called white printing on the first operation unit printing unit 541 and the display unit printing unit 542 with a light-shielding paint, for example, on a transparent glass or transparent resin plate. Configured.

  The capacitance sensor 55 is configured by a sheet-like member having translucency. The capacitance sensor 55 includes a detection unit 57 as a detection electrode for detecting a change in capacitance. The detection unit 57 includes a plurality of first operation unit detection units 571 corresponding to the first operation unit 51 and one second operation unit detection unit 572 corresponding to the second operation unit 52. The electrostatic capacity sensor 55 detects a user's touch operation by detecting a change in electrostatic capacity between the detection unit 57 and the user's finger, for example. In this case, the first operation unit detection unit 571 detects a touch operation on the first operation unit 51 via the printing member 54 and the outer plate 40. Similarly, the second operation unit detection unit 572 detects a touch operation on the second operation unit 52 via the printing member 54 and the outer plate 40.

  As shown in FIG. 3, the apparatus main body 56 is configured such that a circuit board 58 is accommodated in a case 59. The circuit board 58 has a plurality of light source units 60 and an operation control unit 61 shown in FIG. The light source unit 60 includes a plurality of first operation unit light source units 601 corresponding to the first operation unit 51 and a plurality of display unit light source units 602 corresponding to the display unit 53. The light source unit 60 is composed of, for example, an LED and is mounted on the circuit board 58. The light source unit 60 is separated from the printing member 54 and the capacitance sensor 55 in the thickness direction of the case 59 by a light shielding unit 591 formed in the case 59, and another light source unit 60 provided on the circuit board 58. Shielded from light.

  The operation control unit 61 includes a microcomputer (not shown) mounted on the circuit board 58. As shown in FIG. 4, the operation control unit 61 is connected to the main control device 42, and is also connected to the light source unit 60 and the detection unit 57 of the capacitance sensor 55. The operation control unit 61 detects and processes the touch operation input to the capacitance sensor 55 and transmits it to the main control device 42, and controls lighting and extinction of the light source unit 60 based on a command from the main control device 42. To do. In this case, the detection unit 57 detects a user's touch operation performed on the first operation unit 51 or the second operation unit 52 via the printing member 54 and the outer plate 40.

  On the outer plate 40 of the refrigerator compartment door 33 in which the operation device 50 is incorporated, a light transmitting region 404 is formed in a region surrounded by a two-dot chain line in FIG. The translucent area 404 is an area having a slightly smaller shape than the outer shape of the printing member 54. Since the light-shielding layer 401 is not provided in the light-transmitting region 404, the light-transmitting region 404 is light-transmitting. The operation area 402 and the display area 403 are provided in the translucent area 404. In addition, a second operation unit printing unit 405 for displaying the second operation unit 52 is provided in the translucent area 404. The second operation unit printing unit 405 is formed by printing a light-shielding paint or the like on the inside of the outer plate 40. In this case, the translucent region 404 has translucency in a portion other than the second operation unit printing unit 405.

  In this configuration, when the first operation unit light source unit 601 is turned on, the light of the first operation unit light source unit 601 that is turned on is detected by the detection unit 57 of the capacitance sensor 55 and the first operation unit print of the printing member 54. The portion 541 and the light transmitting region 404 of the outer plate 40 are transmitted. As a result, the content of the first operation unit 51 corresponding to the lighted first operation unit light source unit 601, that is, the content of the first operation unit printing unit 541 is displayed so as to float on the outer plate 40. Similarly, when the light source unit 602 for the display unit is turned on, the light of the light source unit 602 for the display unit that has been turned on passes through the display unit print unit 542 of the print member 54 and the translucent region 404 of the outer plate 40. As a result, the content of the display unit 53 corresponding to the lit display unit light source unit 602, that is, the content of the display unit printing unit 542 is displayed so as to float on the outer plate 40. On the other hand, the contents of the second operation unit 52, that is, the contents of the second operation unit printing unit 405 are always displayed on the outer plate 40.

  Next, specific configurations of the first operation unit 51, the second operation unit 52, and the display unit 53 will be described with reference to FIG. The plurality of first operation units 51 includes a refrigeration operation unit 511, a freezing operation unit 512, a freezing function operation unit 513, an ice making operation unit 514, and a power saving operation unit 515. When the first operation unit 51 is simply used, the refrigeration operation unit 511, the freezing operation unit 512, the freezing function operation unit 513, the ice making operation unit 514, and the power saving operation unit 515 are collectively referred to. Each first operation unit 51 includes a character corresponding to the operation content and a circle surrounding the character. The plurality of first operation units 51 are arranged side by side on a vertical line, that is, arranged in a vertical line in the vertical direction.

  The refrigeration operation unit 511 is used to set the degree of cooling of the storage rooms 12 and 13 in the refrigeration temperature zone, and is configured by enclosing the letters “refrigeration” in a circle. The refrigeration operation unit 512 is used to set the degree of cooling of the storage rooms 14, 15 and 16 in the refrigeration temperature zone, and is configured by enclosing the characters “freezing” in a circle. The refrigeration function operation unit 513 is used to set operation details for the upper freezer compartment 15 and is configured by enclosing the characters “refrigeration function” in a circle. The ice making operation unit 514 is used to set operation details for the ice making chamber 14 and is configured by enclosing the characters “ice making” in a circle. The power saving operation unit 515 is used to set an operation mode related to power saving, and is configured by enclosing the characters “power saving” in a circle.

  Moreover, the 2nd operation part 52 is called a home button, and is comprised by the figure part which designed the form clearly different from the form of the 1st operation part 51, for example, the shape of a house. The form means a shape, a pattern, a color, or a combination thereof. The second operation unit 52 determines the operation content set by the operation of the first operation unit 51, invalidates the first operation unit 51, so-called key lock, and activates the first operation unit 51, so-called key lock release. Used to do. The 2nd operation part 52 is provided in the position different from the upper side on the vertical line of each 1st operation part 51 located in a line in a line. In this case, the second operation unit 52 is provided below the first operation unit 51 in a line with each first operation unit 51.

  The display unit 53 is arranged in a line in the vertical direction in parallel with the left side of the first operation unit 51 and the second operation unit 52. The plurality of display units 53 include, for example, an intensity display unit 531, a refrigeration function display unit 532, an ice making display unit 533, a power saving display unit 534, an eco mode display unit 535, and a key lock display unit 536. The strength display portion 531 is composed of a circular portion divided into five equal parts in the circumferential direction and character portions of “strong” and “weak”. The intensity display unit 531 is located in the middle in the vertical direction between the refrigeration operation unit 511 and the freezing operation unit 512. The intensity display unit 531 corresponds to the refrigeration operation unit 511 and the refrigeration operation unit 512, and indicates the strength of the cooling degree of the storage rooms 12, 13 in the refrigeration temperature zone or the storage rooms 14, 15, 16 in the refrigeration temperature zone in five stages. .

  When the user touches the refrigeration operation unit 511, the strength display unit 531 displays the strength of cooling currently set for the storage rooms 12 and 13 in the refrigeration temperature zone. Thereafter, when the refrigeration operation unit 511 is further touch-operated, the display number of the circular portion of the strength display unit 531 is changed, and the strength of cooling of the storage rooms 12 and 13 in the refrigeration temperature zone is changed. On the other hand, when the user performs a touch operation on the refrigeration operation unit 512, the strength display unit 531 displays the strength of cooling currently set for the storage rooms 14, 15, 16 in the refrigeration temperature zone. Thereafter, when the refrigeration operation unit 512 is further touch-operated, the display number of the circular portion of the strength display unit 531 is changed, and the cooling strength of the storage rooms 14, 15, 16 in the refrigeration temperature zone is changed.

  The refrigeration function display unit 532 is composed of four types of character parts: “freezing at once”, “freezing hot food”, “freezing vegetables”, and “dry”. The refrigeration function display unit 532 corresponds to the refrigeration function operation unit 513 and is provided at substantially the same height as the refrigeration function operation unit 513. When the user repeats the touch operation of the refrigeration function operation unit 513, the state in which “freezing at once” is displayed, the state in which “hot frozen” is displayed, the state in which “vegetable freezing” is displayed, and “dry” is displayed. The displayed state and the state in which none of “freezing at once”, “freezing of hot food”, “freezing of vegetable”, and “dry” are sequentially switched. Accordingly, the user selects the operation content for the upper freezer compartment 15 by touching the refrigeration function operation unit 513 while viewing the refrigeration function display unit 532. In this case, regarding each operation content displayed on the freezing function display unit 532, “freezing at once” freezes food faster than usual, “freeze hot” freezes hot food, “freeze vegetable” In the case of freezing raw vegetables, “dry” indicates an operation suitable for freezing in which the moisture of the vegetables is removed.

  The ice making display unit 533 is composed of two types of character parts, “Ice ice making” and “Ice making off”. The ice making display unit 533 corresponds to the ice making operation unit 514 and is provided at substantially the same height as the ice making operation unit 514. When the user repeats the touch operation of the ice making operation unit 514, the state where “Ice ice making” is displayed, “Ice ice making off” is displayed, and “Ice ice making” and “Ice making off” are not displayed. Switch sequentially. Thus, the user selects the operation content for the ice making chamber 14 by touching the ice making operation unit 514 while watching the ice making display unit 533. In this case, regarding each operation content displayed on the ice making display unit 533, “Ice ice making” indicates an operation when ice is made earlier than usual, and “Ice making off” indicates an operation when ice is not made.

  The power saving display unit 534 is composed of three types of character parts, “power saving”, “outing”, and “peak shift”. The power saving display unit 534 corresponds to the power saving operation unit 515 and is provided at substantially the same height as the power saving operation unit 515. When the user repeats the touch operation of the power saving operation unit 515, “power saving” is displayed, “outing” is displayed, “peak shift” is displayed, and “power saving” and “outing” are displayed. , “Peak shift” is sequentially displayed in a state where neither is displayed. Thus, the user sets the operation mode related to power saving by touching the power saving operation unit 515 while looking at the power saving display unit 534. In this case, the main controller 42 shifts to the power saving mode when “power saving” is selected, shifts to the outing mode when “outing” is selected, and shifts the peak when “peak shift” is selected. Enter mode.

  The eco mode display unit 535 is configured with a character portion of “eco mode”. The eco mode display unit 535 is displayed when the door is not opened and closed and the cooling operation is stable. The key lock display unit 536 is configured by a graphic portion in which the shape of the key is designed. The key lock display unit 536 is displayed when the first operation unit 51 is disabled and is in a key lock state.

Next, the control content regarding the operating device 50 by the operation control part 61 is demonstrated with reference to FIG. 7 and FIG.
The operation control unit 61 has a normal mode shown in FIG. 7 and a standby mode shown in FIG. The normal mode is a state in which the operation control unit 61 accepts a touch operation on the first operation unit 51, that is, a so-called key that can change settings related to the operation of the refrigerator 10 when the user touches the first operation unit 51. It is unlocked. The standby mode is a state in which the operation control unit 61 does not accept a touch operation on the first operation unit 51, that is, a so-called key lock state in which the user cannot change settings related to the operation of the refrigerator 10. The operation control unit 61 is in one of the normal mode and the standby mode while the refrigerator 10 is powered on. The operation control unit 61 switches to the standby mode when the second operation unit 52 is operated for a predetermined period during the normal mode or when the first operation unit 51 is not operated for a predetermined period. Further, the operation control unit 61 switches to the normal mode when the second operation unit 52 is operated in a predetermined manner during the standby mode.

  Specifically, as illustrated in FIG. 7, when the operation control unit 61 shifts to the normal mode, first, the first operation unit 51 is first validated in step S <b> 11 and a touch operation on the first operation unit 51 is accepted. The key lock is released. At this time, the operation control unit 61 turns on the first operation unit light source unit 601 to display the first operation unit 51 and lights up the display unit light source unit 602 corresponding to the current setting content. A display unit 53 showing the setting contents is displayed.

  Thereafter, in step S12, the presence / absence of an operation on the first operation unit 51 is detected. When an operation on the first operation unit 51 is not detected (NO in step S12), the process proceeds to step S14. On the other hand, when operation with respect to the 1st operation part 51 is detected (it is YES at step S12), it transfers to step S13 and performs a setting change process. In the setting change process, the operation control unit 61 controls the lighting of the display light source unit 602 according to the operation input to the first operation unit 51 and displays the content of the selected display unit 53. In the setting change process in step S13, the content selected by the operation of the first operation unit 51, that is, the content displayed on the display unit 53 is not yet reflected in the actual operation.

  Thereafter, the operation control unit 61 determines whether or not the key lock operation and the setting change are confirmed in steps S14 and S15. If the second operation unit 52 has been operated continuously for a predetermined period, for example, 3 seconds or more (YES in step S14), the operation control unit 61 determines that there has been a key lock and setting change confirmation operation, and step S16. Migrate to On the other hand, when there is no continuous operation for 3 seconds or more in the second operation unit 52 in step S14 (NO in step S14), the process proceeds to step S15.

  The operation control unit 61 has no continuous operation for a predetermined period with respect to the second operation unit 52 (NO in step S14), and a predetermined period, for example, 10 seconds or more has elapsed since the last operation of the first operation unit 51. If not (NO in step S15), it is determined that the operation on the first operation unit 51 has not ended yet, the process proceeds to step S12, and steps S12 to S15 are repeated. On the other hand, the operation control unit 61, when a predetermined period, for example, 10 seconds or more has elapsed since the last operation of the first operation unit 51, that is, when the first operation unit 51 has not been operated continuously for 10 seconds or more. (YES in step S15), it is determined that the operation on the first operation unit 51 is completed, and the process proceeds to step S16.

  In step S <b> 16, the operation control unit 61 determines the content of the display unit 53 displayed in the display area 403 as the content after the setting change, and sends the content after the setting change to the main control device 42. As a result, the main controller 42 operates by reflecting the operation content after the setting change. Thereafter, the operation control unit 61 shifts to the standby mode shown in FIG.

  When the operation control unit 61 shifts to the standby mode, first, in step S21, the first operation unit 51 is disabled, and a state in which a touch operation on the first operation unit 51 is not accepted, that is, a so-called key lock state is set. At this time, the operation control unit 61 controls the light source unit 60 to display the key lock display unit 536 and erases the display of the display unit 53 other than the first operation unit 51 and the key lock display unit 536. That is, in the key lock state, only the second operation unit 52 and the key lock display unit 536 are displayed in principle, and the eco mode display unit 535 is also displayed according to the operating state of the refrigerator 10.

  Thereafter, the operation control unit 61 detects whether or not a predetermined operation has been performed on the second operation unit 52 in step S22. If the second operation unit 52 is not operated (NO in step S22), the operation control unit 61 maintains the key lock state by repeating step S22 and continuing the standby mode. On the other hand, when a predetermined operation is performed on the second operation unit 52 (YES in step S22), the key lock state is released and the operation on the first operation unit 51 is accepted, so the mode is shifted to the normal mode. In this case, in step S22, the predetermined operation for determining the release of the key lock may be an instantaneous touch operation on the second operation unit 52, a so-called single press operation, or a predetermined period for the second operation unit 52, for example, 3 seconds or more. The continuous operation may be a so-called long press operation.

  According to this, the refrigerator 10 includes the first operation unit 51 that receives an operation for setting the operation of the refrigerator 10, the operation control unit 61 that controls switching between the normal mode and the standby mode, and the normal mode from the standby mode. And a second operation unit 52 that receives an operation for switching to the second operation unit. The operation control unit 61 does not accept an operation for the first operation unit 51 during the standby mode, and switches to a normal mode for accepting an operation for the first operation unit 51 when the second operation unit 52 is operated during the standby mode. For this reason, even if a part of the user's body accidentally touches the first operation unit 51, the first operation unit 51 is not accepted during the standby mode because operations on the first operation unit 51 are not accepted. It is possible to reduce the occurrence of erroneous operations on the.

Further, the operation from the standby mode to the normal mode, that is, the key lock release operation is performed on the second operation unit 52. That is, the key unlocking operation is limited to the second operation unit 52 instead of the plurality of first operation units 51. For this reason, it is possible to reduce the probability of erroneously performing a key lock release operation, and to suppress the occurrence of an erroneous operation.
Further, when the predetermined operation for the second operation unit 52 for releasing the key lock is a so-called single press operation, the troublesomeness due to the key lock release operation can be reduced as much as possible. It is possible to more effectively reduce key lock release due to erroneous operation of the unit 52.
In addition, the capacitance sensor 55 is used to detect the operation of the first operation unit 51 and the second operation unit 52. According to this, the surface of the outer plate 40 of the refrigerator compartment door 33 provided with the operating device 50 can be made flat, and the design can be improved.

  The plurality of first operation units 51 are arranged in a vertical line on the vertical line. According to this, the design by arrangement | positioning of the some 1st operation part 51 can be made favorable. Here, in the case of this embodiment, since the capacitance sensor 55 is used for detection of the first operation unit 51, an erroneous operation may occur due to the liquid adhering to the first operation unit 51. Since the plurality of first operation parts 51 are arranged in a vertical line on the vertical line, liquid adheres to the upper side of the first operation part 51, and the liquid moves vertically downward along the surface of the outer plate 40. When drooping, the first operation unit detection units 571 corresponding to the plurality of first operation units 51 arranged in a vertical row may react sequentially to cause an erroneous operation. In this case, an erroneous operation occurs with respect to the plurality of first operation units 51, so that the setting contents completely different from the setting contents intended by the user are arbitrarily changed.

  Therefore, in the present embodiment, the second operation unit 52 is provided at a position different from the upper side on the vertical line of the plurality of first operation units 51 arranged in a vertical row. That is, the second operation unit 52 is not provided on the upper side of the first operation unit 51 vertical line. According to this, even when the liquid adheres above the first operation unit 51 and the liquid hangs vertically downward, the key lock state is not released unless the liquid drips on the second operation unit 52. The first operation unit 51 is never erroneously operated. Therefore, even if the first operation unit 51 is easily misoperated due to liquid adhesion, that is, even if the first operation unit 51 is arranged in the vertical direction using a capacitance sensor, an erroneous operation due to liquid application Can be effectively reduced.

  Furthermore, in the present embodiment, the second operation unit 52 is provided below the first operation unit 51 and arranged side by side with the first operation unit 51. For this reason, when a liquid drips on the upper side of the first operation unit 51, the liquid first drops after being dropped on the second operation unit 52 due to the arrangement of the first operation unit 51 and the second operation unit 52. It does not hang down on the operation unit 51. That is, the liquid does not touch the first operation portion 51 after touching the second operation portion 52 to release the key lock state. For this reason, the first operation unit 51 and the second operation unit 52 are arranged in a vertical row to obtain a good design, and liquid is applied when the first operation unit 51 and the second operation unit 52 are arranged in a vertical row. The erroneous operation due to can be more effectively suppressed.

  Moreover, the 1st operation part 51 is used for the setting of the driving | operation regarding power saving. In this case, the power saving operation unit 515 is used to set the power saving mode, the outing mode, and the peak shift mode as operations related to power saving. According to this, the user can easily save power by simply touching the power saving operation unit 515, and as a result, it can contribute to avoiding large-scale power outages and planned power outages.

  The second operation unit 52 is configured in a form that is clearly different from the form of the first operation unit 51. In the case of the present embodiment, the first operation unit 51 has a form in which a character part is surrounded by a circle, whereas the second operation unit 52 is configured by a graphic part in which the shape of a house is designed. According to this, since the difference between the first operation unit 51 and the second operation unit 52 can be appealed to the user's vision, the user clearly identifies the first operation unit 51 and the second operation unit 52. Can be distinguished. Thereby, the erroneous operation of the 2nd operation part 52 by a user can be reduced more effectively, As a result, the erroneous operation with respect to the 1st operation part 51 can also be reduced more effectively.

(Second embodiment)
Next, a second embodiment will be described with reference to FIG.
In the second embodiment, the operation method of the second operation unit 52 is different from that of the first embodiment. That is, in the second embodiment, the predetermined operation for releasing the key lock state during the standby mode is more complicated than the operation method for the first operation unit 51. In this case, as the predetermined operation, a so-called slide operation is adopted in which the user's finger is linearly moved in either one of left and right or up and down directions. In FIG. 8, the user operates from left to right as a slide operation. In this case, the second operation unit 52 is configured by enclosing a figure which is a house design in a long rectangle in the direction of the slide operation. Further, the second operation unit detection unit 572 of the capacitance sensor 55 is configured by arranging the second operation unit detection unit 572 divided into a plurality along the direction of the slide operation, although details are not illustrated. ing. And the operation control part 61 detects that the slide operation was performed by detecting operation which switches to the direction of a slide operation sequentially about the detection part 572 for 2nd operation parts divided | segmented into plurality.
According to this, since the user can clearly distinguish the predetermined operation by the second operation unit 52 for releasing the key lock state during the standby mode from the operation of the first operation unit 51, the user can The operation mistake by the 1st operation part 51 by the 2nd operation part 52 can be reduced.

Further, the predetermined operation for releasing the key lock state is more complicated than the operation method for the first operation unit 51. Therefore, in order to operate the second operation unit 52 and release the key lock state, the user needs to operate the second operation unit 52 with a clear intention to operate the second operation unit 52. For this reason, for example, when the user accidentally touches the second operation unit 52 in an attempt to operate the first operation unit 51, it is possible to prevent the key lock state from being released as much as possible.
Furthermore, in the second embodiment, in order to release the key lock state, it is not sufficient to simply touch the second operation unit 52, and a certain operation from left to right is required. For this reason, even when the liquid hangs down on the second operation unit 52, it is possible to avoid the operation of the second operation unit 52 as much as possible.

(Third embodiment)
Next, a third embodiment will be described with reference to FIG.
In the third embodiment, like the second embodiment, the operation method of the second operation unit 52 is mainly different from the first embodiment. That is, in the third embodiment, the predetermined operation for releasing the key lock state during the standby mode is more complicated than the operation method for the first operation unit 51. In this case, a so-called wheel operation in which the user's finger is moved in the circumferential direction is used as the predetermined operation. In this case, the second operation unit 52 is configured by enclosing a figure in which a house is designed with a double circle. In addition, the second operation unit detection unit 572 of the capacitance sensor 55 is configured by arranging a plurality of divided second operation unit detection units 572 along the circumferential direction, although not shown in detail. Yes. And the operation control part 61 detects that wheel operation was performed by detecting operation which switches to the direction of wheel operation sequentially about the detection part 572 for 2nd operation parts divided | segmented into plurality.

  According to this, the same effect as 2nd embodiment can be acquired. Furthermore, since the outer shape of the second operation unit 52 can be the same circle as the outer shape of the first operation unit 51, the first operation unit 51 and the second operation unit 52 are arranged in the vertical direction. A sense of unity arises and a good design can be obtained.

(Fourth embodiment)
Next, a fourth embodiment will be described with reference to FIG.
In the fourth embodiment, a second operation unit 70 is provided instead of the second operation unit 52. The second operation unit 70 differs from the first operation unit 51 in the operation detection method. That is, the second operation unit 70 is configured by a mechanical push button type switch. The second operation unit 70 is provided in the apparatus main body 56, and a notch 551 formed in the capacitance sensor 55, a window 543 formed in the printing member 54, and a window 406 formed in the outer plate 40. And exposed to the surface of the outer plate 40. According to this, since the operation detection method and the operation method are clearly different between the first operation unit 51 and the second operation unit 70, erroneous operation of the first operation unit 51 and the second operation unit 70 is more effective. Can be reduced.

  Furthermore, since the first operation unit 51 uses a capacitance sensor and the second operation unit 70 uses a mechanical switch, the first operation unit 51 and the second operation unit 70 are operated by a user during operation. The necessary operating force and the feeling given to the user can be completely different. Thereby, since the user can distinguish the difference between the first operation unit 51 and the second operation unit 70 from both visual and tactile senses, an erroneous operation of the first operation unit 51 and the second operation unit 70 can be performed. It can reduce more effectively. The second operation unit 70 may use a resistance film type switch or a pressure sensor.

(Fifth embodiment)
Next, a fifth embodiment will be described with reference to FIG.
In the fifth embodiment, a second operation unit 71 is provided instead of the second operation units 52 and 70 described above. The second operation unit 71 differs from the first operation unit 51 in an operation detection method. That is, the second operation unit 71 uses the non-contact sensor 72 to detect an operation on the second operation unit 71. The non-contact sensor 72 is, for example, an infrared sensor or an illuminance sensor. In this case, the non-contact sensor 72 detects a change in external light through the outer plate 40.
According to this, the operation of the second operation unit 71 is not limited to the case where the second operation unit 71, that is, the outer plate 40 is directly touched and operated, for example, the hand is held or approached to the second operation unit 71. The operation by can also be performed. Thereby, the operation mode of the 2nd operation part 71 can be made various, As a result, the operativity improvement regarding the operation of the 2nd operation part 71 is achieved.

The detection of the operation of the first operation unit 51 is not limited to that by the capacitance sensor 55, and various sensors or switches such as a pressure sensor, a resistance film type switch, a mechanical switch, an infrared sensor, and an illuminance sensor are employed. can do.
Further, the main control device 42 may be configured to include the operation control unit 61.
Moreover, the form of the 1st operation part 51, the 2nd operation parts 52, 70, 71, and the display part 53 is not restricted to the character and figure in said each embodiment. Further, the function corresponding to the operation of the first operation unit 51 is not limited to that of each of the above embodiments. In addition, the second operation units 52, 70, 71 are not limited to being arranged in the vertical direction on the first operation unit 51, and may be arranged on the left side or the right side of the first operation unit 51.
Further, the second operation unit printing unit 405 may be provided on the printing member 54 instead of the outer plate 40.
In each of the above embodiments, the operating device 50 may be incorporated in any of the vegetable compartment door 34, the ice making compartment door 35, the upper freezer compartment door 36, and the lower freezer compartment door 37.

  According to the configuration of the embodiment described above, the operation control unit normally receives an operation on the first operation unit when the second operation unit is operated during the standby mode in which the operation on the first operation unit is not accepted. Switch to mode. According to this, even if a part of the user's body or liquid accidentally touches the first operation unit, the first operation unit is not accepted during the standby mode. Occurrence of erroneous operations on the operation unit can be reduced.

  Although several embodiments of the present invention have been described, these embodiments are 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 equivalents thereof.

  In the drawings, 10 refrigerators, 11 is a heat insulating box, 33 is a door, 51 is a first operation unit, 52, 70 and 71 are second operation units, 55 is a capacitance sensor, 61 is an operation control unit, and 72 is non- A contact sensor is shown.

Claims (1)

An insulated box having an opening;
A door for opening and closing the opening;
A first operation unit that is provided on a front surface of the door and receives an operation for changing a setting related to operation of the refrigerator;
An operation control unit that switches between a normal mode that accepts an operation on the first operation unit and a standby mode that does not accept an operation on the first operation unit;
A second operation unit provided on the front surface of the door and receiving an operation for switching from the standby mode to the normal mode;
The operation control unit is a refrigerator that switches to the normal mode when the second operation unit is operated during the standby mode.

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