JP6313383B2 - refrigerator - Google Patents

Description

  Embodiments of the present invention relate to refrigerators.

  2. Description of the Related Art Conventionally, an operation panel provided on a refrigerator door has an operation switch for instructing an operation on the front surface of the panel and a display unit for displaying the operation result.

  In recent years, some of these operation switches are constituted by capacitive touch switches. In this touch switch, an electrode for touch detection is provided on the back side of the operation switch. When a user's finger contacts the operation switch, a current flows between the human body and the electrode, so that the capacitance of the electrode changes. When the control unit detects that the capacitance changes, the control unit determines that the user's finger has touched the operation switch, and causes a light emitting element such as an LED to emit light. Thereby, light emitting elements, such as LED, make the display part of an operation panel shine.

JP 2011-58787 A

  However, when using the capacitive touch switch as described above, the door opening operation may cause the conductive material around the refrigerator to come close to the touch sensor, causing the operation unit to malfunction. There was a problem.

  Therefore, in view of the above-described problems, an embodiment of the present invention aims to provide a refrigerator that can prevent malfunction even when a peripheral conductive material is close to a touch switch by a door opening operation.

Embodiments of the present invention include a refrigerator main body, a door that is rotatably provided on the refrigerator main body via a hinge portion, a front plate provided on a front surface of the door, a front plate , and An operation region and a display region for setting functions of the refrigerator chamber, an operation unit having a capacitance detection unit in the operation region of the front plate, and an open / closed state of the door provided in the refrigerator body (1) While the door detection switch detects the open state, the operation of the operation unit is invalidated while the door detection switch detects the open state, and the door is on the surface of the door that is rotated and opened. Even if the capacitance detection unit of the operation unit is close to the conductive material, malfunction is prevented , and (2) the capacitance detection unit does not detect a change in capacitance, and the door detection switch is closed. When the status is detected, the control unit cancels the invalid operation. A refrigerator and having a part, a.

The disassembled perspective view of the operation panel unit of this embodiment. The perspective view of the refrigerator of this embodiment. The perspective view of the state which removed the operation panel unit from the door. The front view which shows the display state of an operation panel unit. The longitudinal cross-sectional view of an operation panel unit. FIG. 3 is a partially enlarged longitudinal sectional view of the operation panel unit. The front view of a half mirror vapor deposition film. The perspective view which looked at the operation panel unit of the state which removed the display board from the back side. The perspective view which shows a state when removing an operation board. The front view of an operation board. The rear view of an operation board. The block diagram of a refrigerator and an operation panel unit. The flowchart which shows the operation state of a display control part.

  Hereinafter, the refrigerator 10 of one Embodiment is demonstrated based on FIGS.

(1) Structure of refrigerator 10 The structure of the refrigerator 10 is demonstrated based on FIG.

  As shown in FIG. 2, the refrigerator 10 includes a refrigerator main body 11 having a vertically long rectangular box shape. The inside of the refrigerator body 11 is divided into a storage room in a refrigeration temperature zone and a storage room in a refrigeration temperature zone. A refrigeration room 12 and a vegetable room 13 are provided in order from the top, and an ice making room 14 and a small freezer are provided below the vegetable room 13. The chamber 15 is provided side by side on the left and right, and the main freezer compartment 16 is provided at the bottom.

  The refrigeration room 12 and the vegetable room 13 are storage rooms in a refrigeration temperature zone in which the inside temperature is controlled to a refrigeration temperature of about 1 ° C. to 5 ° C.

  The ice making room 14, the small freezer room 15, and the main freezer room 16 are storage rooms in a freezing temperature zone in which the inside temperature is controlled to a freezing temperature of, for example, -18 ° C or lower.

  A refrigeration cycle including a compressor, a condenser, and an evaporator (not shown) is provided at the rear part of the refrigerator main body 11 in order to cool the storage compartment in the refrigeration temperature zone and the storage compartment in the refrigeration temperature zone.

  The refrigerator compartment 12 is a double door with a front opening and closing by two rectangular doors 17 and 18.

  The front of each of the vegetable compartment 13, the ice making compartment 14, the small freezer compartment 15, and the main freezer compartment 16 is opened and closed by drawer type doors 20, 21, 22, and 23.

  In addition, the main body 60 of the refrigerator 10 is provided in the refrigerator body 11 (see FIG. 12).

(2) Doors 17 and 18 of the refrigerator compartment 12
The structure of the two double doors 17 and 18 of the refrigerator compartment 12 is demonstrated based on FIG. 2 and FIG.

  The doors 17 and 18 of the refrigerator compartment 12 are a double door type that is rotated in the front-rear direction around hinges 19 a and 19 b provided at the left and right ends of the front portion of the refrigerator body 11. Inside the doors 17 and 18, a foam heat insulating material made of urethane foam or the like (not shown) is provided.

  Among the two doors 17 and 18, as shown in FIG. 3, a vertical rectangular recess 24 whose front side is open is provided in the front portion of the left door 17 when viewed from the front. The concave portion 24 is provided with a vertically long rectangular parallelepiped operation panel unit 25 in a housed state.

  Moreover, the door detection switch 70 which detects each opening / closing state of the doors 17 and 18 of the refrigerator compartment 12, and another door is provided in the refrigerator main body 11, respectively (refer FIG. 12).

(3) Operation panel unit 25
The configuration of the operation panel unit 25 will be described with reference to FIG.

  As shown in FIG. 1, the operation panel unit 25 includes a front plate 26, an operation substrate 27, a display substrate 28, a half mirror vapor deposition film (hereinafter simply referred to as “mirror film”) 29 that constitutes a semi-transmissive member, and a diffusion film. 30 and an intermediate support member 31.

  The front plate 26 is made of a synthetic resin having translucency, and is formed in a rectangular shape that is long in the vertical direction (see the direction of arrow A in FIG. 1). The front plate 26 has an operation area 32 for setting functions related to the refrigerator compartment 12 and the freezer compartments 15 and 16, and a display area 33 for displaying the operation results.

  The operation area 32 is a square area surrounded by an alternate long and two short dashes line in FIG. The operation area 32 is divided into four cross-shaped lines. In the operation area 32, operation display sections such as “refrigeration room, automatic door off”, “freezer room, power saving”, “freezing function, key lock”, “swift ice making, ice making off” are directly printed on the front plate 26. The touch switch 32a is formed.

  The display area 33 is a rectangular area surrounded by a two-dot chain line in FIG. 1 above the front plate 26, and the function display portions 46 and 66 are displayed.

(4) Operation board 27
The configuration of the operation board 27 will be described with reference to FIGS.

  As shown in FIGS. 10 and 11, the operation board 27 has a substantially square shape, and four electrodes 34 serving as a capacitance detection unit constituting the capacitance type touch switch 32a are provided at a predetermined interval on the front surface. It is arranged in a grid pattern on the top, bottom, left and right. Each electrode 34 is a capacitance detection unit, and is formed in a rectangular shape. In addition, a through hole 36 penetrates the central portion of the lower portion of the rectangular electrode 34. The “through hole 36” is obtained by coating a conductive material on the inner peripheral surface of a hole penetrating from the front surface to the rear surface of the operation substrate 27. Therefore, the electrode 34 on the front surface of the operation board 27 and the connection line 35 extending from the through hole 36 are electrically connected. The four electrodes 34 are arranged corresponding to the back sides of the four touch switches 32a in the operation area 32, respectively, and are arranged in a wider range than the characters of the corresponding touch switch 32a.

  A rectangular parallelepiped connector 37 is directly fixed to the lower portion of the rear surface of the operation board 27 and protrudes from the rear surface.

  The connection lines 35, 35 extending from the through holes 36, 36 corresponding to the two electrodes 34, 34 in the upper stage are wired in the central portion of the operation board 27 and then the gap between the lower electrodes 34, 34. And is connected to a connector 37 provided on the lower rear surface of the operation board 27. Further, the connection lines 35, 35 extending from the through holes 36, 36 corresponding to the lower electrodes 34, 34 are also wired to the central portion of the operation board 27 and then connected to the connector 37. Each connection line 35 is wired so as not to interfere with each other.

  On both sides of the operation board 27, a pair of left and right cutouts 38, 38 are opened outward. The role of the notch 38 will be described later.

(5) Display board 28
The configuration of the display substrate 28 will be described with reference to FIGS. 1, 3, and 6. FIG.

  As shown in FIG. 1, the display substrate 28 has a rectangular shape that is approximately the same size as the front plate 26. A plurality of LEDs 40, each constituting a light emitting element, are intensively surface-mounted on the upper part of the front surface of the display substrate 28, and a switch control unit 41, a display control unit 42, and an operation board connection connector 43 are provided on the lower part of the front surface. A main body connector 44 is provided at the lower corner. The plurality of LEDs 40 are arranged to be positioned behind the display area 33 of the front plate 26. Each LED 40 has directivity.

  As shown in FIG. 6, the lower portion of the display board 28 and the operation board 27 overlap each other, the connector 37 provided on the back surface of the operation board 27, and the operation board connection connector 43 provided on the front surface of the display board 28. And are connected.

  Although not shown, the display board 28 has a wiring pattern for connecting the operation board connecting connector 43 and the switch control unit 41, a wiring pattern for connecting the display control unit 42 and each LED 40, and a display control unit 42. A wiring pattern for connecting to the main body connector 44 is formed. Further, the height of the LED 40 mounted on the front surface of the display board 28 and the mounted electrical component is lower than the height of the operation board connection connector 43, and the height of the operation board connection connector 43 is lower. use.

  The main body connection connector 44 is provided at the lower corner of the display substrate 28 and is connected to the main body side connector 45 provided in the recess 24 of the door 17 as shown in FIGS. The main body side connector 45 is connected to a main control unit 60 (not shown) provided on the refrigerator main body 11 side of the refrigerator 10.

  In addition, no electrical components are mounted on the back surface of the display substrate 28.

(6) Mirror film 29
The mirror film 29 has a rectangular shape slightly smaller than the front plate 26 and is located between the front plate 26 and the intermediate support member 31. The mirror film 29 is disposed at a position that does not overlap the operation substrate 27.

  As shown in FIG. 7, the mirror film 29 has functions such as characters representing the operation of the refrigerator such as “refrigeration room”, “vegetable room”, “freezer room”, “freezing”, “power saving mode”, etc. A display 46 and a function display 66 for displaying the function of the refrigerator, such as “eco (where“ eco ”is a trademark” in the drawings and the description), are displayed. In this part, a metal film reflecting light, for example, aluminum is provided by vapor deposition. When the mirror film 29 is irradiated with light from the back side, the function display portions 46 and 66 transmit light but do not transmit other portions.

(7) Diffusion film 30
The diffusion film 30 has a rectangular shape slightly smaller than the mirror film 29 and is located between the mirror film 29 and the intermediate support member 31.

  The diffusion film 30 has an action of diffusing light from the LEDs 40 of the display substrate 28. That is, the diffusion film 30 expands the light irradiation area of the LED 40.

(8) Intermediate support member 31
The intermediate support member 31 is made of synthetic resin and has an irradiation member 64 having a plurality of irradiation tube portions 47 respectively corresponding to the plurality of LEDs 40, a diffusion film storage portion 48, a half mirror vapor deposition film storage portion (hereinafter simply referred to as “mirror film storage”). 49) and the operation board housing member 50 are integrated.

  The irradiation member 64 is a rectangular frame-shaped member provided on the upper part of the intermediate support member 31, and the operation substrate housing member 50 is a frame-shaped member provided on the lower part of the intermediate support member 31. The members 50 and 64 are integrally molded.

(8-1) Diffusion film accommodating part 48
The diffusion film accommodating portion 48 is a portion of a plate surrounded by the frame portion of the frame-shaped irradiation member 64. That is, the diffusion film accommodating portion 48 is provided in a rectangular shallow concave shape inside the frame portion of the frame-shaped irradiation member 64 and accommodates the diffusion film 30.

(8-2) Irradiation tube portion 47
The irradiation cylinder portion 47 is provided so as to protrude rearward from the diffusion film accommodating portion 48 corresponding to the position of each LED 40 provided on the display substrate 28. Each irradiation tube portion 47 is provided with a rectangular opening 52 (see FIG. 8) on the back side of the intermediate support member 31. Each opening 52 is provided so as to surround each LED 40 provided on the display substrate 28. That is, one opening 52 is provided so as to surround the periphery of one LED 40 corresponding thereto. Each irradiation tube portion 47 extends in a cylindrical shape in a direction from each opening 52 toward the front plate 26, and is formed so as to spread outward in a trumpet shape toward the front portion. Each irradiation tube portion 47 ensures a certain distance from the opening 52 to the front plate 26. Thereby, the irradiation member 64 of the intermediate support member 31 secures a space between the display substrate 28 and the front plate 26.

(8-3) Mirror film accommodating part 49
A step portion is provided in the frame portion of the frame-shaped irradiation member 64, and a large rectangular shallow concave shape is formed outside the diffusion film accommodating portion 48, and this shallow concave shape corresponds to the mirror film accommodating portion 49. . The mirror film 29 is accommodated in the mirror film accommodating portion 49. The mirror film accommodating portion 49 is laminated on the front side (front plate 26 side) from the diffusion film accommodating portion 48.

  The lower edge portion of the mirror film accommodating portion 49 on the operation substrate 27 side is set at the same position as the lower edge portion of the diffusion film accommodating portion 48.

  The function display portions 46 and 66 of the mirror film 29 are located between the four walls of the corresponding irradiation tube portion 47. The four walls of one irradiation tube portion 47 extend from the opening 52 to one function display portion 46. That is, one function display unit 46 (or 66) is located in a rectangular frame region surrounded by the irradiation tube unit 47 corresponding thereto. The LED 40 corresponding to the function display unit 46 (or 66) is located in the opening 52 of the corresponding irradiation tube unit 47. As a result, the light of the LED 40 is diffused only inside the corresponding irradiation tube portion 47 and irradiated to the corresponding function display portion 46.

(8-4) Operation board housing member 50
Two engaging portions 53 protrude from the left and right inner side portions of the frame portion of the frame-shaped operation board housing member 50, and three presser portions 55, 56, and 57 protrude from the upper edge portion.

  The two engaging portions 53 are located substantially at the center in the vertical direction on both the left and right inner portions of the operation substrate housing member 50 and project inward to support the operation substrate 27.

  The three pressing portions 55, 56, and 57 are positioned at the upper edge portion on the mirror film accommodating portion 49 side in the peripheral edge portion of the operation substrate accommodating member 50, and are provided so as to be elastically deformable. Protrusions 58, 58, 59 projecting forward are integrally provided on the front surface of the three pressing portions 55, 56, 57, and these projecting portions 58, 58, 59 support the operation board 27 from the back surface. To do.

  The two engaging portions 53 and the three pressing portions 55, 56, 57 are provided on the rear side by the thickness of the operation board 27 from the front plate 26 side of the intermediate support member 31. That is, the engaging portion 53 and the presser portions 55, 56, and 57 are provided on the side opposite to the front plate 26 of the intermediate support member 31 by the thickness of the operation board 27. Thus, in the state where the operation substrate 27 is accommodated in the operation substrate accommodation member 50 and the mirror film 29 is accommodated in the mirror film accommodation portion 49, the front surface of the operation substrate 27 and the front surface of the mirror film 29 are shown in FIG. Are located on substantially the same plane.

  In the state in which the operation substrate 27 is accommodated in the operation substrate accommodation member 50, as shown in FIG. 8, a gap 62 is formed between the lower edge portion of the operation substrate accommodation member 50 and the lower edge portion of the operation substrate 27. . The role of the gap 62 will be described later.

  In a state where the operation substrate 27 is accommodated in the operation substrate accommodating member 50, the center of the operation region 32 of the front plate 26 is arranged at a position slightly shifted from the center of the electrode 34. That is, the center of the operation area 32 is positioned in a direction away from the connection line 35.

(8-5) Member for Fixing Display Substrate 28 A member for fixing the display substrate 28 will be described with reference to FIGS.

  As shown in FIG. 8, three display substrate support claws 51 are provided in a state of being opposed to each other on both the left and right sides of the frame portion on the back side of the intermediate support member 31, for a total of six. The display substrate 28 is supported by the display substrate support claws 51 so as to be sandwiched from both the left and right sides.

  As shown in FIGS. 5 and 8, a boss portion 63 having a screw hole 63 a is integrally provided near the lower edge portion of the operation substrate housing member 50 on the back side of the intermediate support member 31. On the other hand, a screw insertion hole 64 (see FIG. 1) is formed in a portion corresponding to the boss portion 63 in the display substrate 28. The display substrate 28 is fixed to the back side of the intermediate support member 31 by screwing the screw 65 inserted through the screw insertion hole 64 into the screw hole 63a of the boss portion 63 from the back side of the display substrate 28.

(9) Fixed state of parts The diffusion film 30 and the mirror film 29 are sandwiched and fixed between the front plate 26 and the intermediate support member 31 while being accommodated in the diffusion film accommodating portion 48 and the mirror film accommodating portion 49. The

  The front plate 26 and the intermediate support member 31 are fixed with an adhesive or the like.

  The operation board 27 is supported by the engaging portion 53 and the holding portions 55, 56, and 57, and is also supported and fixed by the operation board connecting connector 43 and the connector 37. The operation board 27 is in contact with or close to the back surface of the front plate 26 while being accommodated in the operation board accommodation member 50.

  The display substrate 28 is fixed by being screwed with screws 65 while being supported on the intermediate support member 31 by the six display substrate support claws 51.

(10) Method for assembling operation panel unit 25 A method for assembling the operation panel unit 25 having the above configuration will be described.

  First, the operation substrate 27 is accommodated in the operation substrate accommodating member 50 so as to be placed on the engaging portion 53 and the presser portions 53, 56, and 57 from the front side of the intermediate support member 31.

  Next, the diffusion film 30 is accommodated in the diffusion film accommodation portion 48 of the intermediate support member 31.

  Next, the mirror film 29 is accommodated in the mirror film accommodating portion 49 of the intermediate support member 31.

  Next, the front plate 26 is superimposed on the front surface of the intermediate support member 31, and the front peripheral edge portion of the intermediate support member 31 and the rear peripheral edge portion of the front plate 26 are bonded and fixed with an adhesive.

  Next, the display substrate 28 is disposed behind the intermediate support member 31, and the display substrate 28 is held by the display substrate support claws 51 of the intermediate support member 31. At this time, the operation board connection connector 43 on the front surface of the display board 28 is connected to the connector 37 on the rear surface of the operation board 27. By connecting the connector 37 and the operation board connection connector 48, the operation board 27 is supported on the display board 28 as shown in FIG.

  Next, the display substrate 28 is attached and fixed to the back side of the intermediate support member 31 by screwing the screws 65 into the screw holes 63 a of the boss portion 63 from the back side of the display substrate 28. Thus, the assembly of the operation panel unit 25 is completed.

  Next, the main body connection connector 44 is connected to the main body side connector 45 on the recess 24 side.

  Finally, the operation panel unit 25 is accommodated in the recess 24 of the door 17. Thereby, the operation panel unit 25 is attached to the door 17.

(11) Method of Removing Operation Board 27 Next, a case where the operation board 27 is removed from the operation panel unit 25 in order to check, repair, and replace the operation board 27 will be described with reference to FIG.

  First, the operation panel unit 25 is removed from the recess 24 of the door 17.

  Next, the display board 28 is removed from the intermediate support member 31 by removing the screws 65 from the screw holes 63 a and releasing the display board support claws 51. At this time, the operation board connector 48 and the connector 37 of the operation board 27 are also removed.

  Next, as shown in FIG. 9, the operation substrate 27 is slid downward (in the direction of the arrow A <b> 1) in the operation substrate housing member 50 while the intermediate support member 31 and the front plate 26 are bonded. At this time, since the gap 62 is present, the operation board 27 can be slid downward.

  Next, when sliding, the two engaging portions 53, 53 protruding from the operation board housing member 50 move to the positions of the notched portions 38, 38, so that the engaging portions 53 are moved by the notched portions 38, 38. The operation board 27 can be detached from the operation board housing member 50 without hitting the operation board 27.

(12) Electrical Configuration of Refrigerator 10 Next, an electrical configuration centering on the operation panel unit 25 in the refrigerator 10 will be described based on the block diagram of FIG.

  The switch control unit 41 is connected to the four electrodes 34 described above, and each electrode 34 corresponds to the touch switch 32a.

  A switch control unit 41 and a plurality of LEDs 40 are connected to the display control unit 42, respectively. As will be described later, the display control unit 42 performs lighting control so as to perform dynamic lighting or static lighting for each LED 40. The display control unit 42 is connected to the main control unit 60 built in the refrigerator main body 11. Furthermore, the display control unit 42 has two modes. The first mode is a standby mode in which the user waits for the touch switch 32a to be operated, and the second mode is a mode in which the user touches the touch switch 32a. Is an operation mode in which the operation can be executed.

  The main control unit 60 is connected to door detection switches 70 and 70 provided on the doors 17 and 18, respectively, and further connected to door detection switches 70 provided on other doors. These door detection switches 70 output an opening / closing signal to the main control unit 60 when the doors 17 and 18 are opened. The main control unit 60 controls the refrigerator 10 based on the content of the operation of the operation panel unit 25 by the user in the operation mode. For example, the main control unit 60 is in a refrigerator temperature zone consisting of the refrigerator compartment 12 and the vegetable compartment 13. The temperature is controlled to a predetermined temperature, and the internal temperature of the freezing temperature zone composed of the ice making chamber 14, the small freezing chamber 15 and the main freezing chamber 16 is controlled to a predetermined temperature.

(13) Method for turning on / off the LED 40 A method for turning on / off the LED 40 will be described.

  The lighting control of all the LEDs 40 is controlled by the display control unit 42. Methods for turning on / off the LED 40 include static lighting and dynamic lighting (pulse lighting).

  “Static lighting” is a method in which the LED 40 is always energized and continuously lit.

  “Dynamic lighting” is also referred to as “pulse lighting”, and PWM control (pulse width modulation control) is performed by an inverter circuit built in the display control unit 42, and gradation control is performed by changing the power supply rate to the LED 40. . This energization rate is determined by the duty ratio (Duty ratio) stored in the display control unit 42. Then, the LED 40 is repeatedly turned on and off to be lit in a pulsed manner so that the human eye is always lit. Moreover, when this energization rate (duty ratio) is made high, the value of the flowing current increases and the brightness of the LED 40 increases.

  By the way, the display area 33 is divided into a function display section 66 that is always lit and a function display section 46 that is lit only during operation. Therefore, regarding the function display unit 66, in the standby mode in which no operation is performed, the display control unit 42 always lights the LED 40 by dynamic lighting, and switches from dynamic lighting to static lighting in the operation mode. With respect to the function display unit 46, the display control unit 42 performs dynamic lighting only during lighting in the operation mode, and performs static lighting after complete lighting.

  As described above, static lighting is performed for both the function display units 46 and 66 in the operation mode. If dynamic lighting is used, pulsed high-frequency noise is generated, which may cause malfunction in the capacitive touch switch 32a. Therefore, static lighting is performed to prevent noise generation. On the other hand, in the standby mode other than the operation mode, the LED 40 that is constantly lit is dynamically lit (pulse lighting) to save power.

(14) Operation state at the time of door opening / closing Next, the operation state of the refrigerator 10 when the door 17 or the door 18 is opened and closed is demonstrated based on the flowchart of FIG. In addition, although the following description demonstrates in the state when the door 17 was opened and closed in the doors 17 and 18, the door 18 is also the same.

  First, the display control unit 42 executes a standby mode that waits for a user operation in a normal state. Further, in the standby mode, the display control unit 42 causes the LED 40 corresponding to the function display unit 66 that is always lit in the display area 33 to dynamically light (pulse lighting) at a predetermined duty ratio. As a result, even if the LED 40 is always lit, power saving can be achieved.

  In step S1, the main control unit 60 determines whether or not the door 17 is closed based on an open / close signal from the door detection switch 70. If the door 17 is closed, the process proceeds to step S3 (in the case of Y), and the door 17 is closed. If is open, the process proceeds to step S9 (in the case of N).

  In step S2, when the user operates the touch switch 32a with a finger while the door 17 is closed, the switch control unit 41 detects whether or not the capacitance C has changed in the electrode 34, If there is no change, the process returns to step S1 (in the case of N), and if there is a change, the process proceeds to step S3 (in the case of Y). That is, when the user's finger contacts the touch switch 32 a in the operation area 32 of the front plate 26, a current flows between the human body and the electrode 34 of the operation board 27, thereby changing the capacitance C of the electrode 34. The switch control unit 41 detects the change in the capacitance C and compares it with the reference capacitance C0 in a state where no conductor is in proximity. When C> C0, the user's finger is a touch switch. It is determined that the touch switch 32a has been touched, and an operation signal corresponding to the touch switch 32a that has been operated on the assumption that the touch switch 32a has been turned on is output.

  In step S3, the display control unit 42 turns on the LED 40. That is, the display control unit 42 statically lights the LED 40 corresponding to the operation based on the operation signal from the switch control unit 41, and switches the LED 40 that is always lit from dynamic lighting (pulse lighting) to static lighting. In static lighting, since current is always supplied, noise does not occur and the capacitive touch switch 32a does not malfunction. When the LED 40 emits light, the light is irradiated to the mirror film 29 from the back side through the diffusion film 30 and the corresponding function display units 46 and 66 are illuminated. At this time, since each LED 40 is individually surrounded by the irradiation tube portion 47, the light emitted from the LED 40 is not leaked to the other, and only the corresponding function display portions 46 and 66 can be illuminated well. As shown in the display state of FIG. 4, the user can see the illuminated function display units 46 and 66 by viewing the front plate 26 from the front of the operation panel unit 25. Then, the process proceeds to step S4.

  In step S4, the main control unit 60 detects again whether or not the open / close signal is output from the door detection switch 70, that is, whether or not the door 17 is closed, and if it is closed, the process proceeds to step S5 (Y ), If the door 17 is open, the process proceeds to step S7 (in the case of N).

  In step S5, since the state where the door 17 is closed continues, the switch control unit 41 determines again whether or not the capacitance C in the electrode 34 has changed. If the operation of the user's finger has changed, the process returns to step S4 (in the case of N), and if C <= C0, the operation by the user's finger has not changed and the process proceeds to step S6. That is, if the door 17 is in a closed state until the switch control unit 41 no longer detects a change in the capacitance C of the electrode 34, the process proceeds to step S6. Note that “until no change in the capacitance C of the electrode 34 is detected” means that the user's finger is in contact with or close to the electrode 34 as described in the above step, and the detection of the state continues. Means that the change in capacitance C is not detected.

  In step S6, since the door 17 was not opened until the switch control unit 41 no longer detects the change in the capacitance C of the electrode 34, the display control unit 42 performs the operation performed by the user. Switch to operation mode. And the main control part 60 controls the refrigerator 10 corresponding to a user's operation, and when that control is completed, the process returns to step S1 to return to the standby mode.

  In step S7, since the door 17 is in the open state, the display control unit 42 changes the light emission state of the LED 40. That is, regarding the light emission state of the LED 40, the state when the door 17 is closed and the state when the door 17 is open are changed. For example, when the door 17 is open, the brightness of the LED 40 is lowered or turned off compared to when the door 17 is closed. Alternatively, when the light emission state of the LED 40 is different between the operation mode and the standby mode, the light emission state of the operation mode is switched from the light emission state of the operation mode to the standby mode. Then, the process proceeds to step S8.

  In step S8, the switch control unit 41 cancels the operation of the touch switch 32a detected in step S2, and proceeds to step S10. As a result, when the user operates the touch switch 32a, the door 17 is opened, and the operation signal is output erroneously even though the operation is stopped while the door 17 is open. Can be prevented. The reason is that when the switch control unit 41 detects a change in the capacitance C of the electrode 34 and then detects no change in the capacitance C, when the door detection switch 70 detects an open state, This is because a malfunction can be prevented by canceling the operation.

  In step S9, since the door 17 is in an open state, the light emission state of the LED 40 is changed as in step S7, and the process proceeds to step S10.

  In step S10, since the door is in an open state, subsequent user operations are invalidated and the process proceeds to step S11.

  In step S11, the switch control unit 41 compares the capacitance C of the electrode 34 with the reference capacitance C0. That is, it is determined whether or not the touch switch 32a has been operated. If C <= C0, the process returns to step S1 (in the case of N). If C> C0, it is determined that the touch switch 32a has been operated, and the process proceeds to step S12 (in the case of Y).

  In step S12, the main control unit 60 determines whether or not the door 17 is closed based on the open / close signal from the door detection switch 70. If the door 17 is closed, the process proceeds to step S13 (in the case of Y) and is opened. Return to step S10 (in the case of N). Thus, it can be determined whether or not the door 17 has been closed once opened.

  In step S13, the switch control unit 41 compares the capacitance C of the electrode 34 with the reference capacitance C0. If C> C0, the process returns to step S12, and if C <= C0, the process returns to step S1. . That is, it is determined whether or not the touch switch 32a is operated by a user's finger, and if not operated, the process returns to step S1, and if operated, the process returns to step S12 to detect the open / closed state of the door 17 again. As a result, the subsequent user operation is invalidated in step S10, but the invalid state is canceled by returning to step S1 again.

(15) Effects According to the refrigerator 10 of the above embodiment, the following effects can be obtained.

  According to this embodiment, while the door 17 or the door 18 is open, the operation by the touch switch 32a is invalidated. Therefore, even if the opened door 17 or the door 18 is close to the conductive material, the touch switch 32a is There is no malfunction. Further, the user can be notified that the operation is invalid by dimming or extinguishing the LED 40. In addition, since the light is dimmed and extinguished, an effect of reducing power can be achieved. In addition, you may alert | report to a user that operation is invalid by making it the light emission state by standby mode.

  Further, when the user operates the touch switch 32a, when the door 17 or the door 18 is opened, the signal from the electrode 34 is erroneously detected even though the operation is stopped while the door 17 or 18 is opened. In order to prevent the detected state from being detected, a change in the capacitance of the electrode 34 is detected, and then the door detection switch 70 is opened until no change in the capacitance is detected. When detected, malfunction can be prevented by invalidating the operation.

  Further, when the switch control unit 41 does not detect a change in capacitance and the main control unit 60 detects the closed state by the door detection switch 70, the operation is made effective so that the user can The operation that continues while the door 17 is open can be validated, and the user cannot perform the operation unless the doors 17 and 18 are closed.

  In addition, four electrodes 34 are provided on the front surface of the operation board 27, and connection lines 35 are wired on the back surface. The electrodes 34 and the connection lines 35 are connected by through holes 36. For this reason, the user's finger does not touch or approach the connection line on the rear surface of the operation board 27, so that the capacitive touch switch can be prevented from malfunctioning. Further, since the connection line 35 is on the rear surface of the operation board 27, the connection line 35 is not rubbed with the front plate 26 covering the operation board 27, and the connection line 35 is not broken.

  Further, since the operation board 27 and the display board 28 are connected by the connector 37 and the operation board connection connector 43, the path of the signal line can be shortened and malfunction due to noise can be prevented. Further, since the operation substrate 27 is fixed to the display substrate 28 by the connector 37 and the operation substrate connection connector 43, other components such as a spacer can be omitted, and the cost can be reduced. Further, the connection by the connectors 37 and 43 has a shorter line length and is more resistant to noise than a flat cable.

  In addition, the display substrate 28 on which the LEDs 40 are surface-mounted is positioned behind the operation substrate 27, and the intermediate support member 31 for securing a space between the front plate 26 and the display substrate 28 is provided. The light of the LED 40 is diffused and applied to the display area 33 of the front plate 26, and a sufficient irradiation area can be secured in the display area 33 of the front plate 26.

  Further, since the connector 37 and the operation board connecting connector 43 are arranged at the lower part of the display board 28 and the plurality of LEDs 40 are arranged at the upper part of the display board 28, the connectors 37, 43 and the LED 40 are separated from each other. And the influence of the noise which LED40 generate | occur | produces can be suppressed.

  Further, since the connection lines 35 of the operation board 27 are wired together in the central portion of the operation board 27, the area of each electrode 34 can be increased.

  Further, since the connection line 35 does not overlap any electrode 34, the influence from the electrode 34 can be prevented.

  In addition, since the through hole 36 is provided on the side portion (lower part) of the electrode 34 in the direction in which the connection line 35 extends, there are few portions where the electrode 34 and the connection line 35 overlap, and the length of the connection line 35 is reduced. Therefore, the influence of noise can be suppressed.

  Further, since the operation board 27 is provided with only the electrode 34, the connection line 35, and the connector 37, when it is desired to change the shape and number of the electrodes 34, only the operation board 27 may be replaced. Easy to work.

  Further, the center of the operation region 32 is shifted slightly upward with respect to the center of the electrode 34. That is, the center of the operation area 32 is positioned in a direction away from the connection line 35. Thereby, it becomes difficult for a user's finger to touch the upper position of the connection line 35, and disconnection can be further prevented.

  Further, since the LED 40 that is constantly lit is dynamically lit (pulse lighting) except when the user is operating, power saving can be achieved.

  In addition, when the user is performing an operation, the LED 40 that is lit by the operation and the LED 40 that is constantly lit are switched to static lighting, so that high-frequency noise generated from the LED 40 and the display control unit 42 can be suppressed. The malfunction of the capacitive touch switch can be prevented.

  Further, the operation substrate 27 can be easily removed after the display substrate 28 is removed from the intermediate support member 31 with the intermediate support member 31 and the front plate 26 adhered. Therefore, inspection, repair, and replacement of the operation board 27 can be easily performed.

  In addition, the operation board 27 having the touch switch electrode 34 can have the front surface close to or in contact with the back surface of the front plate 26. Thereby, it is possible to accurately detect that the user's finger has touched the touch switch 32a in the operation area 32, and the sensitivity of touch detection is improved.

  Further, the electrode 34 of the operation board 27 is slightly larger than the character of the touch switch 32a, and particularly extends below the character of the touch switch 32a. When operating, the user tends to press the character he / she wants to operate while looking at the characters on the touch switch 32a. For this reason, the user often makes contact below the character of the touch switch 32a. Also in this case, since the electrode 34 extends below the touch switch 32a, it can be accurately detected that the user has touched.

  The intermediate support member 31 has a cylindrical irradiation tube portion 47 extending from the display substrate 28 toward the front plate 26 in a state of surrounding the LED 40 from the periphery. Thereby, the light emitted from LED40 does not leak to others, and the corresponding function display part 46 can be illuminated favorably.

  In addition, a plurality of function display units 46 and 66 are disposed in the display area 33 of the front plate 26, and a plurality of LEDs 40 corresponding to the function display units 46 and 66 are disposed on the display substrate 28. The support member 31 is provided with a plurality of irradiation tube portions 47 for the respective LEDs 40. Thereby, the some function display parts 46 and 66 can be favorably illuminated by LED40 corresponding.

  Further, the operation area 32 and the display area 33 on the front plate 26 are arranged so as not to overlap each other, and the operation board 27 and the display board 28 are arranged so as to partially overlap each other. Are electrically connected via the connector 37 and the operation board connecting connector 43 provided at the overlapping portions. As a result, the operation board 27 can be reduced in size and simplified, and electrical components such as the LED 40, the switch control unit 41, and the display control unit 42 can be integrated on the display board 28 side.

  Further, the display board 28 has the LED 40, which is an electrical component, the switch control unit 41, the display control unit 42, and the operation board connection connector 43 mounted only on the front surface, and no electrical component is mounted on the back surface. Thereby, the back surface of the display board 28 used as the back surface of the operation panel unit 25 can be closely_contact | adhered to the inner surface of the recessed part 24, and the thickness of the heat insulating material by the side of the door 17 is securable.

  The mirror film 29, which is a semi-transmissive member having a metal film for light reflection, is positioned between the front plate 26 and the display substrate 28 so as not to overlap the operation substrate 27. The function display unit 46 is displayed. Thereby, since the light of a part other than a necessity is reflected, it can prevent that light leaks from the part other than a necessary part to the front side.

  Further, the intermediate support member 31 integrally includes an operation substrate housing member 50 that houses the operation substrate 27 and a mirror film housing portion 49 that houses the mirror film 29. Thereby, the front surface of the operation substrate 27 and the front surface of the mirror film 29 can be substantially flush with each other in a state where the operation substrate 27 and the mirror film 29 are accommodated in the accommodating portions 50 and 49 of the intermediate support member 31.

  Further, the intermediate support member 31 has presser portions 55, 56, and 57 that press the operation board 27 from the back side. These presser portions 55, 56, and 57 can be elastically deformed. Thereby, the operation board 27 can be pressed against the front plate 26 side.

Example of change

  Hereinafter, a modified example of the present embodiment will be described.

(1) Modification 1
In the above embodiment, the light emission state of the LED 40 is changed when the door 17 or 18 is opened. In addition to this, the operation panel unit 25 is additionally provided with an LED 40 that emits light only when the operation is invalidated. . Then, when the door 17 or 18 is opened during operation, the LED 40 indicating invalidity of the operation may be turned on or blinked to notify the user.

(2) Modification example 2
In the said embodiment, although LED40 was used as a light emitting element, you may use light emitting elements, such as a liquid crystal display device other than this, and an organic electroluminescent apparatus.

(3) Modification 3
In the above embodiment, the front plate constituting the front surface of the operation panel unit 25 has been described using the front plate 26 dedicated to the operation panel unit 25. However, the present invention is not limited to this. A front plate may be formed by a plate or the like, and the operation region 32 and the display region 33 may be formed in a part of the front plate.

(4) Modification 4
In the said embodiment, although the vapor deposition material of the mirror film 29 was aluminum, it should just be not only this but a metal.

(5) Modification 5
In the above-described embodiment, the display control unit 42 is provided at a position corresponding to the connection line 35 wired on the operation board 27. The part 42 and the LED 40 may be provided. For example, a part of the operation board 27 may be cut out, and the display control unit 42 or the LED 40 may be arranged below the cut-out part. In this case, it is preferable that the LED 40 is statically lit to prevent noise.

(6) Modification 6
In the above embodiment, the operation area 32 is provided in the upper part of the operation panel unit 25 and the display area 33 is provided in the lower part. Not limited to this, a plurality of operation areas 32 may be provided, and a display area 33 may be formed between these operation areas 32. In this case, the connection line 35 of the operation board 27 is wired between the operation areas 32.

(7) Others Although several embodiments of the present invention have been described, these embodiments are presented as examples and are not intended to limit the scope of the invention. These novel embodiments can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the scope of the invention. These embodiments and modifications thereof are included in the scope and gist of the invention, and are included in the invention described in the claims and the equivalents thereof.

DESCRIPTION OF SYMBOLS 10 ... Refrigerator, 17 ... Door, 25 ... Operation panel unit, 26 ... Front plate, 32 ... Operation area, 32a ... Touch switch, 33 ... Display area, 34. ..Electrodes, 40 ... LED, 41 ... Switch control unit, 42 ... Display control unit, 46 ... Function display unit, 60 ... Main control unit, 70 ... Door detection switch

Claims (2)

The refrigerator body,
A door provided on the refrigerator main body via a hinge part so as to be rotatable,
A front plate provided in front of the door;
An operation area and a display area provided on the front plate and for setting the function of the refrigerator room ,
An operation unit having a capacitance detection unit in the operation region of the front plate;
A door detection switch provided in the refrigerator body for detecting the open / closed state of the door;
(1) While the door detection switch detects the open state, the operation of the operation unit is invalidated, and the capacitance detection of the operation unit on the surface of the door that is rotated and opened parts with prevents malfunction even in proximity to the conductive material, (2) the electrostatic capacitance detecting unit is not detecting a change in capacitance, and, when said door detection switch detects the closed state, the A control unit for canceling the invalidation of the operation of the operation unit;
A refrigerator characterized by comprising: When the door detection switch detects an open state before the capacitance detection unit detects a change in capacitance and then stops detecting the change in capacitance, the control unit Disable the operation of the operation unit,
The refrigerator according to claim 1.

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