JP2015084807A - Washing machine - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a washing machine comprising a slide touch operation unit which hardly causes an erroneous detection.SOLUTION: The washing machine 1 has sequentially arranged first detection electrodes of a capacitance type and a second detection electrode adjacent thereto, which are in an embodiment a plurality of annularly arranged first detection electrodes SP1 to SP10 and a "start-temporary stop" display part 68 which is an example of the second detection electrode that is arranged inside of the plurality of annularly arranged first detection electrodes SP1 to SP10 and is of a capacitance type. A plurality of the first detection electrodes SP4, SP5 are arranged at positions where, when a finger touches a lead-out electrode part 80 of the second detection electrode, the finger can always touch the plurality of the first detection electrodes SP4, SP5.

Description

  Embodiments described herein relate generally to a washing machine.

  Generally, home appliances such as washing machines are provided with an operation panel for performing various settings. For this operation panel, a mechanical switch such as a tact switch is often used. However, when a mechanical switch is used, a plurality of uneven portions due to the mechanical switch are generated on the surface of the operation panel, which causes a complicated impression to the user.

  Therefore, in recent years, it has been proposed to use a touch operation unit that can detect a touch operation with a user's finger instead of a mechanical switch for such an operation panel. As an operation panel of a washing machine, Patent Document 1 proposes a touch operation unit. As described above, when the touch operation unit is used as the operation panel of the washing machine, the operation panel can be flattened, the appearance is neat and troublesome, and waterproof measures can be easily performed.

JP2011-240110A

  By the way, although the touch operation part of patent document 1 has a center start key and the annular electrode in the circumference | surroundings, the wiring of each electrode is not described and how is it from a center start key? It has not been materialized. Therefore, when the lead electrode portion from the center start key is simply pulled out to the outside of the ring in the same plane as the ring electrode, the ring electrode becomes discontinuous at the lead portion, so the user touches it with fingers. When trying to slide the annular electrode, the lead electrode portion may erroneously detect the movement of the finger, and the washing machine may be inadvertently started or erroneously set.

  This invention is made | formed in view of the above, The place made into the objective is providing the washing machine provided with the touch operation part which is hard to generate | occur | produce an erroneous detection.

  A washing machine according to an embodiment of the present invention is a washing machine that includes an operation panel that is provided in a washing machine body and performs various settings, and a control unit that controls the operation panel. Has a slide touch operation unit that operates the content of the setting by touching, and the slide touch operation unit is a plurality of capacitance type detection electrodes arranged in a ring shape, and the finger touches The plurality of detection electrodes for notifying the control unit of the detection and the capacitance-type inner detection electrodes disposed inside the plurality of detection electrodes, The gist of the lead electrode portion from the detection electrode is that the lead electrode portion is always arranged at a position where the finger touches the plurality of detection electrodes adjacent to the detection electrode.

It is a perspective view showing the whole washing machine concerning the embodiment of the present invention. It is a figure which shows the example of an electrical connection containing the control part of the washing machine shown in FIG. It is a figure which shows the state which turned on completely, in order to show the slide touch operation part of an operation panel, an operation key, and a display apparatus. It is a figure which shows the non-lighting state of the operation panel before powering on a washing machine. It is a figure which shows the initial lighting state of the operation panel immediately after power activation of a washing machine. It is a figure which shows the operation example at the time of sliding operation (dial operation) to a rotation direction of a slide touch operation part. It is a figure which shows in detail the structural example of the slide touch operation part shown in FIG. 3 and FIG. It is a figure which shows the example of the display specification when the key operation performed using the slide touch operation part shown in FIG. 6 is performed concretely. It is a figure which shows the example of the display specification when the key operation performed using the slide touch operation part shown in FIG. 6 is performed concretely. It is a figure which shows the example of the display specification when the key operation performed using the slide touch operation part shown in FIG. 6 is performed concretely. It is a figure which shows the slide touch operation part of another embodiment of this invention.

  DESCRIPTION OF EMBODIMENTS Hereinafter, embodiments for carrying out the present invention (hereinafter referred to as embodiments) will be described with reference to the drawings.

  FIG. 1 is a perspective view showing an entire washing machine according to an embodiment of the present invention. FIG. 2 is a diagram illustrating an example of electrical connection including the control unit of the washing machine illustrated in FIG. 1.

  A washing machine 1 shown in FIG. 1 is, for example, a drum-type washing and drying machine having a drying function, and includes a washing machine body 2, a door 3, a control unit 20 shown in FIG. 2, and an electrostatic touch operation panel. 10 is provided. In this washing machine 1, the door 3 side is the front side of the washing machine body 2, and the opposite side of the door 3 is the rear side of the washing machine body 2.

  A washing machine main body 2 shown in FIG. 1 constitutes an outer shell of the washing machine 1 and is formed in a rectangular box shape whose front surface is smoothly inclined. The washing machine main body 2 is configured based on, for example, white. A circular opening 4 is provided in the front center portion of the washing machine body 2. The opening 4 is connected to a rotating tub provided inside the washing machine body 2, and the laundry can be taken in and out of the rotating tub through the opening 4. The door 3 shown in FIG. 1 is provided in the front center part of the washing machine main body 2 so that the opening 4 can be opened and closed. The door 3 can be opened by operating the door button 5.

  A water supply port 6 is provided on the upper surface of the washing machine body 2. The water supply port 6 is connected to a water tap serving as a water source by a water supply hose (not shown). Water from the faucet is supplied to a water tank (not shown) provided in the washing machine body 2 through the water supply hose and the water supply port 6.

  The control unit 20 illustrated in FIG. 2 is connected to a motor 21, a drain valve 22, a water supply valve 23, a compressor 24, a blower 25, and the like. Although a detailed description of these elements is omitted, the motor 21 is for rotating a rotating tub (not shown) provided in the washing machine body 2. The drain valve 22 is for draining water in a water tank (not shown) out of the washing machine 1. The water supply valve 23 opens and closes communication between the water supply port 6 and a water tank (not shown) to supply water into the water tank. The compressor 24 constitutes a heat pump unit for a drying function. The blower 25 supplies the hot air generated by the heat pump unit into the rotating tub.

  As shown in FIG. 2, the control unit 20 is connected to a temperature sensor 26, a water level sensor 27, a rotation sensor 28, a door switch 29, and the operation panel 10. Although a detailed description of these elements is omitted, the temperature sensor 26 detects the temperature in a water tank (not shown). The water level sensor 27 detects the water level in the water tank. The rotation sensor 28 detects the rotation position and rotation speed of the rotation tank. The door switch 29 detects opening and closing of the door 3 in FIG.

  The operation panel 10 shown in FIGS. 1 and 2 performs various settings relating to the operation of the washing machine 1. A configuration example of the operation panel 10 is shown in FIG.

  The operation panel 10 shown in FIG. 3 is in a fully lit state to clearly show the slide touch operation unit 40, various operation keys, and the time display unit 60.

  As shown in FIG. 3, the operation panel 10 includes a power “on” button 31, a power “off” button 32, a slide touch operation unit (for example, a so-called jog dial) 40, a first display region unit 49, and a second display. It has the area | region part 50, the time display part 60, and the 3rd display area part 61. FIG.

  The first display area 49 includes a “filter cleaning” display unit 33A, a “child lock” display unit 33B, a “door lock” display unit 33C, a “clothing offset” display unit 33D, a “tank clean” display unit 33E, It has a “with water in tank” display section 33F, an “Ag antibacterial water” display section 33G, a “capacity over” display section 33H, and an “eco mode” display section 33J.

  This “child lock” is a function that creates a state in which the door 3 cannot be unlocked arbitrarily, and is a function that prevents a child from accidentally unlocking the door 3 and entering the washing tub. When child lock is set, normal operation and operation are possible. However, in the “child lock” state, the locked state is maintained and the door is opened even if the “door lock is unlocked” state, such as before the start of operation, at a temporary stop, or at the end of the operation. But door 3 does not open. The child lock can be set at any timing when the operation is disclosed, during the operation, or after the operation ends. The “door lock” is a function for automatically locking the door 3 when driving.

  Furthermore, as shown in FIG. 3, the operation panel 10 has a deodorizing and antibacterial key 41, a washing key 42, a washing / drying key 43, and a drying key 44 as operation keys. The operation panel 10 is provided with a second display area 50 on the left side of these operation keys. On the left side of the second display area 50, the operation panel 10 has a “wash” key 51, “rinse” key 52, “dehydration” key 53, “dry” key 54 as operation keys, and a digital display type time. A display unit 60 is arranged.

  This time display unit 60 is turned on immediately after the power is turned on to display the current time. During the setting before driving (when the washing time or the user makes a custom), the washing time, the rinsing time, the dehydration time, etc. are displayed. indicate. In addition, the time display unit 60 displays the remaining time until the end of driving during driving. Further, the operation panel 10 has a third display area unit 61 on the left side of the time display unit 60.

  Incidentally, the power “ON” button 31 and the power “OFF” button 32 shown in FIG. 3 are formed at the lower right position of the operation panel 10 by printing. In other words, the power “ON” button 31 and the power “OFF” button 32 allow the user to visually confirm the presence and position of the power “ON” button 31 and the power “OFF” button 32. . It should be noted that only the power “on” button 31 is printed, and the power “off” button 32 is lit when the power “on” button 31 is pressed, so that its presence and position can be visually confirmed. Anyway.

  Inside the operation panel 10 shown in FIG. 3, a plurality of light emitting elements, for example, LED (light emitting diode), EL (electroluminescence), or a liquid crystal display device with a backlight is arranged, and the surface is light of these light emitting elements. It is covered with a semi-transparent white sheet that transmits light. The light emission intensity of these light emitting elements has two stages according to the command of the control unit 20 shown in FIG. 2, and there are a “light up brightly” mode and a “light up darkly” mode.

  Returning to FIG. 3, the slide touch operation unit 40 can be lit and displayed in an annular shape (ring shape) by the light emitting element. Similarly, the power “ON” button 31 and the power “OFF” button 32, the first display area 49, the second display area 50, the third display area 61, the deodorizing antibacterial key 41, and the washing key 42. Also, the washing / drying key 43, the drying key 44, the “washing” key 51, the “rinse” key 52, the “dehydration” key 53, and the “drying” key 54 can be turned on by the light emitting element. The digital display type time display unit 60 can be lit by a light emitting element.

  The slide touch operation unit 40 shown in FIG. 3 is arranged immediately on the left side of the power “on” button 31 and the power “off” button 32, and the operation panel 10 has a slight dent so as to be lit and noticed. Preferably, it is formed in an annular shape. Therefore, when the slide touch operation unit 40 is not lit, the presence of the slide touch operation unit 40 on the surface of the operation panel 10 is hardly conscious. In addition, a “start / pause” display unit 68 is arranged in the center of the slide touch operation unit 40, and a “course / time setting” display unit 69 is arranged in the vicinity of the slide touch operation unit 40. The “start / pause” display unit 68 is also simply referred to as a start key 68.

  The slide touch operation unit 40 shown in FIG. 3 has, for example, four to ten light emitting elements (not shown), for example, six light emitting elements, in order to emit light in an annular shape, and emits these light emitting elements. By doing so, the slide touch operation unit 40 can form a ring-shaped lighting portion 67. These light emitting elements light up and display the dial portion of the slide touch operation unit 40, but always light up before and during driving. As a result, when the power is turned on by pressing the “ON” button 31 of the power source, the slide touch operation unit 40 can be lit up, so that the position and shape of the slide touch operation unit 40 can be clearly displayed to the user.

  FIG. 4 shows a non-lighting state of the operation panel 10 before the washing machine is turned on, and FIG. 5 shows an initial lighting state of the operation panel 10 immediately after the washing machine is turned on.

  As shown in FIG. 4, in the non-lighted state of the operation panel 10 before the user turns on the power of the washing machine, only the printed “on” button 31 and the “off” button 32 of the power are displayed. Since it is displayed, the user can visually confirm the presence and position of the power “on” button 31 and the power “off” button 32.

  Then, as shown in FIG. 5, when the user presses the “ON” button 31 of the power supply shown in FIG. 4 to display the initial lighting of the operation panel 10 immediately after the power is turned on, the slide touch operation unit 40, "Ag antibacterial water" display unit 33G, "eco mode" display unit 33J, deodorizing antibacterial key 41, washing key 42, washing key 43, drying key 44, "standard" display unit 50A, and time display unit The current time of 60 is turned on. In addition, the “start / pause” display unit 68 and the “course / time setting” display unit 69 are lit, and the user can respectively press the “start / pause” key and the “course / time setting” slide touch operation unit 40. Can easily be recognized.

  FIG. 6 shows an operation example when the slide touch operation unit 40 is slid (dial operation) in the rotation direction. This rotational direction is the clockwise direction CW or the counterclockwise direction CCW.

  As shown in FIG. 6, when the user presses the washing / drying button 43, for example, each item in the area 50 </ b> A of the second display area unit 50 is lit. When the user touches the slide touch operation unit 40 with a finger and performs a sliding operation in the rotation direction, the “bright” state of each item in the region 50A is sequentially shifted to each item, and each item that is not in the “bright” state The item is in a “dark” state. Similarly, when the user presses the dryer key 54, for example, each item in another area 50B of the second display area unit 50 is lit. When the user touches the slide touch operation unit 40 with a finger and performs a sliding operation in the rotation direction, the “bright” state of each item in the region 50B is sequentially shifted to each item, and each item that is not in the “bright” state “Dark” state.

  FIG. 7 shows in detail a structural example of the slide touch operation unit 40 shown in FIGS. 3 and 5.

  As shown in FIG. 7, on the sensor sheet 66 of the slide touch operation unit 40, for example, ten detection electrodes SP1 to SP10 (first detection electrodes) are continuously and preferably separated from each other with a predetermined gap. Are arranged in a ring shape (annular). The detection electrodes SP1 to SP10 are made of a conductive polymer having a high light transmittance, and only the outer edge portion 99 is made of a silver carbon paste as a conductive line having a low light transmittance.

  On one side of the detection electrodes SP1 to SP10 arranged in an annular shape, specifically on the inner side of the annular shape, a circular “start / pause” display unit 68 that is preferably concentric with the detection electrodes SP1 to SP10 is arranged. Has been. Corresponding to the “start / pause” display section 68, a capacitance type inner detection electrode 100 (second detection electrode) made of a conductive polymer having high light transmittance is arranged.

  The detection electrodes SP1, SP2, SP3, SP6, SP7, SP8, SP9, and SP10 among the detection electrodes SP1 to SP10 each have an uneven end portion 71 and an uneven end portion 72. One end 71 of each detection electrode SP1, SP2, SP3, SP6, SP7, SP8, SP9, SP10 has two convex peaks 71A and one concave valley 71B between them. . Further, the other end 72 of each of the detection electrodes SP1, SP2, SP3, SP6, SP7, SP8, SP9, SP10 has one convex peak portion 72A and two concave left and right concave portions 72B. doing. Each mountain portion and each valley portion are formed in a triangular shape, for example. The opposing one end 71 and the other end 72 of the detection electrodes SP1, SP2, SP3, SP6, SP7, SP8, SP9, SP10 are arranged close to each other so as not to contact each other with a slight gap therebetween. Thus, they overlap each other in the direction across the detection electrodes SP1 to SP10.

  Further, as shown in FIG. 7, one of the detection electrodes SP1 to SP10 has one end portion 81 formed in a linear shape and the other end portion 72 formed in an uneven shape. . In addition, another detection electrode SP5 among the detection electrodes SP1 to SP10 has one end portion 71 formed in a concavo-convex shape and the other end portion 82 formed in a linear shape.

  The linear one end portion 81 of the detection electrode SP4 and the linear other end portion 82 of the detection electrode SP5 are arranged to face each other with a predetermined interval RT. The linear one end 81 of the detection electrode SP4 and the linear other end 82 of the detection electrode SP5 are formed substantially in parallel along the radial direction of the slide touch operation unit 40.

  Further, the convex / concave end portion 72 of the detection electrode SP4 and the concave / convex end portion 71 of the detection electrode SP3 are arranged close to each other so as not to contact each other with a slight gap (for example, 1 mm). Has been. The uneven end portion 71 of the detection electrode SP5 and the uneven end portion 72 of the detection electrode SP6 are arranged close to each other so as not to contact each other with a slight gap (for example, about 1 mm). ing.

  As shown in FIG. 7, in correspondence with the “start / pause” display portion 68, the inner detection electrodes 100 arranged on the inner sides of the detection electrodes SP <b> 1 to SP <b> 10 arranged continuously in an annular shape are provided. Yes. This inner side detection electrode 100 has a lead-out electrode part 80, and this lead-out electrode part 80 is arranged on the inner side of the annular shape that is one side when viewed from the detection electrodes SP1 to SP10. It extends toward the outer side of the circular ring that is the other side of. That is, the routing electrode portion 80 passes from the inner detection electrode 100 across the interval RT between the linear one end portion 81 of the detection electrode SP4 and the linear other end portion 82 of the detection electrode SP5, and detects It is led out to the outside of the electrode SP4 and the detection electrode SP5.

  The lead electrode portion 80 is a belt-like member, and its width QT is smaller than the interval RT between the linear one end portion 81 of the detection electrode SP4 and the linear other end portion 82 of the detection electrode SP5. If it is 5 mm, QT is set to 1.5 mm. The interval RT is set to a minimum dimension so that the lead electrode portion 80 is led out so as not to contact the detection electrodes SP4 and SP5.

  When a finger touches the slide touch operation unit 40, the width with which the finger touches is, for example, about 8 mm to 20 mm. Considering the width dimension touched by the finger, the interval RT is preferably less than 8 mm, for example.

  Accordingly, in FIG. 7, the user performs a sliding operation along the clockwise direction CW while touching the finger, for example, from the one end 81 of the detection electrode SP4 toward the other end 82 of the detection electrode SP5, and the drawing electrode unit. When trying to pass 80, the finger always touches at least one of the one end portion 81 of the detection electrode SP4 and the other end portion 82 of the detection electrode SP5, thereby avoiding a state where neither of them can be touched. That is, when the user slides along the clockwise direction CW while touching the finger, for example, from one end 81 of the detection electrode SP4 toward the other end 82 of the detection electrode SP5, the finger is connected to one end of the detection electrode SP4. A dead zone region in which both of 81 and the other end portion 82 of the detection electrode SP5 cannot be touched is prevented.

  Conversely, in FIG. 7, even when the user slides the finger along the counterclockwise direction CCW while touching the finger from the other end 82 of the detection electrode SP5 toward the one end 81 of the detection electrode SP4, for example. Is in contact with at least one of the other end portion 82 of the detection electrode SP5 and the one end portion 81 of the detection electrode SP4, and it is possible to avoid a state where neither of them can be touched. That is, when the user slides along the counterclockwise direction CCW while touching the finger, for example, from the other end portion 82 of the detection electrode SP5 toward the one end portion 81 of the detection electrode SP4, the finger moves in addition to the detection electrode SP5. A dead zone region where both the end portion 82 and the one end portion 81 of the detection electrode SP4 cannot be touched is prevented.

  As described above, when the user touches the detection electrode SP1 to SP10 with a finger while sliding along the clockwise direction CW or the counterclockwise direction CCW, one end of each detection electrode SP1 to SP10 is touched. It was set as the structure which the dead zone area | region (discontinuous part) which does not touch either between a part and an other end part does not arise. For this reason, even if the user touches, for example, a small finger or the tip of the finger, the false detection or detection error caused by the finger being unable to touch any of the detection electrodes, i.e., no signal is generated. This eliminates the possibility of occurrence of a missing portion continuously, and prevents a detection error such that the lead electrode portion 80 from the inner detection electrode 100 is erroneously detected during the slide operation of the detection electrodes SP1 to SP10 as will be described later. It becomes possible.

  Further, as shown in FIG. 7, the detection electrodes SP1 to SP10 and the inner detection electrode 100 are light transmissive. In addition, the lead electrode portion 80 includes a portion having a distance RT between the linear one end portion 81 of the detection electrode SP4 and the linear other end portion 82 of the detection electrode SP5. It is composed of a polymer. Therefore, the inner sides of the outer edge portions 99 of the detection electrodes SP <b> 1 to SP <b> 10 including the capacitive inner detection electrode 100 are all made of a conductive polymer having a high light transmittance. On the other hand, on the outside of the outer edge portion 99 of the detection electrodes SP1 to SP10, conductive lines are routed by silver carbon paste to a connector (not shown) for connecting each detection electrode to the circuit board.

  This prevents the detection electrodes SP1 to SP10 and the inner detection electrode 100 from blocking light and casting a shadow on the operation panel 10 when the plurality of light emitting elements of the slide touch operation unit 10 are lit. The appearance of the operation panel 10 can be improved. Similarly, if no shadow is generated in the routing electrode portion 80, the appearance of the operation panel 10 can be further improved.

  The inner detection electrode 100 corresponding to the “start / pause” display unit 68 shown in FIG. 7 is a button for instructing the start of the operation of the washing machine 1, and this circular “start / pause” display unit 68 is used with a finger. Only when the touch is made to press, the inner detection electrode 100 is detected, and an instruction signal for starting the operation of the washing machine 1 is sent to the control unit 20 of FIG. However, when the user performs a sliding operation along the clockwise direction CW or the counterclockwise direction CCW while touching the one end 81 of the detection electrode SP4 and the other end 82 of the detection electrode SP5, the user's finger Is detected by the routing electrode unit 80, the instruction signal is not sent to the control unit 20. In other words, since the lead electrode portion 80 is formed to be as thin as necessary as described above, even if the finger is touched, the change in capacitance does not exceed the threshold value. The instruction signal is controlled not to be generated. As a result, unless the user touches the “start / pause” display section 68 itself with his / her finger, an inadvertent start / pause signal is not sent, and erroneous operations can be prevented.

  Each of the detection electrodes SP1 to SP10 can distinguish each detection electrode touched by the user's finger and detect it as position information, and send the position information as a detection signal to the control unit 20 shown in FIG. Thereby, the control part 20 can judge now which detection electrode SP1-SP10 the user touched with fingers.

  However, in a case where the user touches only one of the detection electrodes, for example, the detection electrode SP3 of the slide touch operation unit 40 in a stationary state so as not to touch the other detection electrodes, the user touches the slide touch operation unit 40. Since no instruction for slide operation is given in the rotation direction, the control unit 20 does not react to any key operation on the slide touch operation unit 40. Thereafter, when the user touches, for example, the detection electrode SP2, which is different from the detection electrode SP3 touched first, the control unit 20 in FIG. 2 determines that the position of the touched detection electrode changes in the counterclockwise direction CCW, that is, slides. For the first time, the key operation in the slide touch operation unit 40 is regarded as valid. Thereby, since key operation can be performed using the slide touch operation part 40, the operativity improvement and the misdetection are prevented.

  8 to 10 show examples of display specifications when the key operation performed using the slide touch operation unit 40 shown in FIG. 7 is specifically performed.

  For the “standard course” highlighted by default when the power is turned on shown in FIG. 8A, for example, it is detected that the detection electrode SP2 shown in FIG. 7 is touched and then the adjacent detection electrode SP3 is touched. Thus, when the slide touch operation unit 40 is slid by “+1” in the direction of the arrow R1 (clockwise), the course display shifts to the highlight display of “saving course” shown in FIG. When the unit 40 is slid by “+1” in the direction of the arrow R1 (clockwise), the display shifts to the highlight display of “memory course” shown in FIG.

  Further, from the “memory course” shown in FIG. 9C, when the slide touch operation unit 40 is slid by “+1” in the direction of the arrow R1 (clockwise), the process shifts to “zab course” shown in FIG. 9D. . When it is desired to return to the previous selected course from this state, the slide touch operation unit 40 is slid by “−1” in the direction of the arrow R2 (counterclockwise) from “Zab-Zab Course” shown in FIG. 9D. Then, it returns to the “memory course” shown in FIG. Then, from the “memory course” shown in FIG. 10E, when the slide touch operation unit 40 is slid by “−1” in the direction of the arrow R2 (counterclockwise), the “saving course” shown in FIG. Can be returned.

  FIG. 11 shows an example of the slide touch operation unit 10 according to another embodiment of the present invention.

  The structure of the slide touch operation unit 10 shown in FIG. 11 is basically the same as the structure example of the slide touch operation unit 10 shown in FIG. Omitted.

  Differences in the structure of the slide touch operation unit 10 shown in FIG. 11 are as follows. The routing electrode portion 80 extending from the inner detection electrode 100 includes a narrow portion 80a that is narrower than the width of the routing electrode portion 80 near the display portion 68 in the LH between the detection electrode S4 and the detection electrode SP5. Have. As a result, the distance RT between the detection electrode SP4 and the detection electrode SP5 can be further reduced, and when the finger touches the narrow portion 80a, the finger always touches the plurality of detection electrodes SP4 and SP5. It will be.

  That is, the distance between a plurality of adjacent detection electrodes SP4 and SP5 for passing the routing electrode portion 80 of the inner detection electrode 100 and the narrow portion 80a of the routing electrode portion 80 is different from the other plurality of detection electrodes SP1. It is below the distance between SP4, SP5 and SP10. For this reason, even if it touches the slide touch operation part 40 with a small finger | toe or the front-end | tip part of a finger, the possibility of generating a misdetection can be eliminated much more reliably. Moreover, in the narrow portion 80a of the routing electrode unit 80, the change in capacitance due to the touch of the finger is further reduced, so that the setting range of the threshold for judging the touch is widened and the degree of freedom is increased, and erroneous detection is surely performed. Can be prevented.

  The routing electrode portion 80 including the narrow portion 80a of the inner detection electrode 100 is made of a conductive polymer having high light transmittance. As a result, when a plurality of light emitting elements of the slide touch operation unit 10 are turned on, it is possible to improve the appearance of the operation panel 10 by preventing extra shadows from being generated in the routing electrode unit 80. , It can be made less noticeable by the thin part.

  Further, the opposing end portions 71 and 72 of the plurality of detection electrodes SP1 to SP4 and SP5 to SP10 are formed in an uneven shape (an example of a shape overlapping in the radial direction) that enters each other at intervals. However, the opposing end portions 81 and 82 of the plurality of detection electrodes SP4 and SP5 in a position for leading the lead-out electrode portion 80 of the inner detection electrode 100 to the outside of the plurality of detection electrodes SP1 to SP10 are irregularities that enter each other. It does not have a shape (an example of a shape overlapping in the radial direction), but is, for example, a straight line. The interval RT between the opposing end portions of the plurality of detection electrodes SP4 and SP5 is a value at which the lead electrode portion 80 of the inner detection electrode 100 can be derived.

  In this way, for example, the opposing end portions 81 and 82 of the plurality of detection electrodes SP4 and SP5 overlap in the radial direction at a position where the routing electrode portion 80 of the inner detection electrode 100 is led out of the plurality of detection electrodes. It is not formed in a shape but is formed in a parallel straight line, and the interval RT between the opposing end portions 81 and 82 of the plurality of detection electrodes SP4 and SP5 leads out the lead-out electrode portion 80 of the inner detection electrode. The value is set as small as possible. For this reason, when the user slides while touching the finger, for example, in the clockwise direction CW or counterclockwise direction CCW between the detection electrodes SP4 and SP5, the finger detects both the detection electrodes SP4 and SP5. Non-detection areas that cannot be made more difficult. For this reason, even if the user touches the slide touch operation unit with a small finger or the tip of the finger, there is no possibility of erroneous detection or detection error, that is, the signal becomes discontinuous and missing.

  That is, the “start / pause” display unit 68 corresponding to the inner detection electrode 100 is a button for instructing the operation start of the washing machine 1. The instruction signal for starting the operation of the washing machine 1 is sent to the control unit 20 when the finger touches the “start / pause” display unit 68, but the finger touches the narrow part 80 a of the routing electrode unit 80. In this case, even if the finger is touched, the change in capacitance does not exceed the threshold value, so that the control unit 20 does not recognize the touch and does not start the operation of the washing machine 1.

  Thus, when the user touches the detection electrodes SP4 and SP5 with the fingers along the clockwise direction CW or the counterclockwise direction CCW, the user's fingers touch the lead electrode portion 80 (the narrow portion 80a). However, since the instruction signal is not sent to the control unit 20 and the control unit 20 is not inadvertently sent a start or pause signal, erroneous operation of the washing machine 1 can be prevented.

  As mentioned above, although embodiment of this invention was described, embodiment is shown as an example and is not intending limiting the range of invention. The novel embodiment can be implemented in various other modes, and various omissions, replacements, and changes can be made without departing from the spirit 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.

  The structure of the washing machine 1 shown in FIG. 1 is an example, and an arbitrary structure can be adopted. The structure of the washing machine 1 shown in FIG. 1 is an example, and an arbitrary structure can be adopted. For example, as shown in FIG. 3, the slide touch operation unit 40 is preferably formed in an annular shape, but is not limited thereto, and may be formed in, for example, an elliptical shape, an oval shape, a rectangular shape, The shape may be a straight line, a parallel line, or a semicircular shape.

  As shown in FIG. 7, the slide touch operation unit 40 includes, for example, 10 detection electrodes SP1 to SP10. However, the slide touch operation unit 40 is not limited to this, and includes, for example, 2 or more, 9 or less, or 11 or more detection electrodes. You may make it have.

  For example, when the user performs a sliding operation along the clockwise direction CW or the counterclockwise direction CCW while touching the one end 81 of the detection electrode SP4 and the other end 82 of the detection electrode SP5, the user's finger Is detected by the lead-out electrode portion 80, but when the one end portion 81 of the detection electrode SP4 and the other end portion 82 of the detection electrode SP5 are touched, an inadvertent start or pause signal is sent to the control portion 20. It is good also as a structure which prevents the misoperation of the washing machine 1 by setting it as control without.

DESCRIPTION OF SYMBOLS 1 Washing machine 2 Washing machine main body 3 Door 4 Opening 5 Door button 10 Operation panel 20 Control part 40 Slide touch operation part 68 "Start / pause" display part 80 Leading electrode part SP1-SP10 Detection electrode

Claims (7)

A washing machine provided with an operation panel that is provided in the washing machine body and performs various settings, and a control unit that controls the operation panel,
The operation panel has a slide touch operation unit that operates the contents of the setting by touching with fingers.
The slide touch operation unit
A plurality of capacitance-type sensing electrodes that are continuously arranged; a first sensing electrode that detects that the finger has touched and detects the sensing; and
A capacitance type second detection electrode that is disposed adjacent to one side of the first detection electrode and detects that a finger has touched;
A lead-out electrode portion that pulls out the second detection electrode so as to cross from one side of the first detection electrode to the other side, and a part of the drawing electrode portion overlaps the finger in a direction crossing the first detection electrode Each of the first detection electrodes is disposed at a position where the first detection electrode always touches the first detection electrode when touched.   The distance between the adjacent first detection electrodes and the routing electrode portions for passing the routing electrode portions of the second detection electrodes is equal to or less than the distance between the other first detection electrodes. The washing machine according to claim 1, wherein:   3. The washing machine according to claim 2, wherein a width of the routing electrode portion is set to be not more than twice a distance between the other first detection electrodes.   The opposing end portions of the plurality of first detection electrodes are formed in a shape overlapping in a direction transverse to each other at intervals, and the plurality of first detection electrodes in a position where the routing electrode portion of the second detection electrode crosses 4. The washing machine according to claim 2, wherein the opposite end portions are not shaped to overlap each other in the transverse direction.   The washing machine according to claim 2, wherein the routing electrode portion of the second detection electrode has light permeability.   The washing machine according to claim 1 or 2, wherein the second detection electrode has light permeability.   The second detection electrode is an electrode for instructing the start of the operation of the washing machine by sending a signal that detects that the finger has touched to the control unit, and touched the lead electrode unit at the same time. 7. The washing machine according to claim 2, wherein the control unit is configured not to start the operation of the washing machine.

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