JP6875492B2 - refrigerator - Google Patents

Description

Embodiments of the present invention relate to refrigerators.

Some refrigerators are provided with an operation unit (also referred to as an operation panel unit or the like) on the door for switching the operation mode or the like. A plurality of buttons for operation are displayed on the operation unit, and electrodes of a capacitance type sensor are provided on the back side of each button display. When a conductor such as a human finger approaches or touches a button, a capacitance is generated between the conductor and the electrode of the capacitive sensor, and the amount of electric charge accumulated in the electrode of the capacitive sensor changes. The microcomputer detects this, and the control unit provided in the refrigerator performs control corresponding to the button (see, for example, Patent Document 1).

By the way, the refrigerator door has a structure in which a heat insulating material is packed between the door front plate provided on the outside of the refrigerator and the door inner plate provided on the inside of the refrigerator. The operation unit is provided between the door front plate and the heat insulating material (see, for example, Patent Document 1). In such a refrigerator door, the door front plate shall be translucent, and the door shall have a metallic luster when viewed from the outside of the refrigerator by providing a metal film on the heat insulating material side of the door front plate. Is being considered. In that case, in order to make the entire door have a metallic luster, a metal film is also provided between the door front plate and the operation unit provided with the electrodes of the capacitance type sensor.

Japanese Unexamined Patent Publication No. 2014-40960

However, in refrigerator doors as described above, there is a demand for improvement in appearance that a wide range of doors should be colored.

Therefore, it is an object of the present invention to provide a refrigerator having a further improved appearance.

The refrigerator of the embodiment is a refrigerator provided with a door for opening and closing the opening of the storage chamber, and the doors include a door front plate provided on the outside of the refrigerator, a door inner plate provided on the inside of the refrigerator, and the above. A heat insulating material provided between the door front plate and the door inner plate, an electrode of a capacitance type sensor provided between the door front plate and the heat insulating material, the door front plate and the static. It is provided with a translucent metal-containing layer provided between the electrode of the capacitance type sensor, and between the door front plate and the metal-containing layer on the outside of the electrode of the capacitance type sensor. It is characterized in that a colored layer having translucency is provided on the door.

The front view of the refrigerator 10 of this embodiment. FIG. 1 is a cross-sectional view taken along the line XX of FIG. FIG. 5 is a plan view of a metal film having a small parasitic capacitance in Modification 4. FIG. 5 is a plan view of a metal film having a small parasitic capacitance in Modification 4. FIG. 1 is a cross-sectional view taken along the line XX of FIG. 1 of the refrigerator door in the fifth modification. FIG. 1 is a cross-sectional view taken along the line XX of FIG. 1 of the refrigerator door in the fifth modification. FIG. 1 is a cross-sectional view taken along the line YY of the refrigerator door in Modification 6. FIG. 1 is a cross-sectional view taken along the line YY of the refrigerator door in Modification 6. FIG. 1 is a cross-sectional view taken along the line YY of the refrigerator door in Modification 6. FIG. 1 is a cross-sectional view taken along the line YY of the refrigerator door in Modification 7.

The refrigerator 10 of this embodiment will be described with reference to the drawings. In the drawings, the size of the members and the like may be exaggerated for the sake of explanation.

The refrigerator 10 of the present embodiment includes a cooling cycle device that generates cold air and a control unit such as a microcomputer. The control unit controls the cooling cycle device and sends the cold air generated by the cooling cycle device to the storage chamber to keep the storage chamber at a low temperature. At the back of the storage room, there is an outlet for cold air into the storage room.

The main body of the refrigerator 10 is formed by combining an outer box forming the outer shell of the refrigerator 10 and an inner box in which a storage chamber is formed, and a heat insulating material is packed between the outer box and the inner box. Between the outer box and the inner box, a vacuum heat insulating panel may be provided in which the inside of the box body is filled with glass wool or the like and then exhausted.

As shown in FIG. 1, a plurality of storage chambers are provided in the main body of the refrigerator 10 of the present embodiment, and an opening in front of each storage chamber can be opened and closed by a door. The number and types of storage chambers are not limited, but for example, in the refrigerator 10 of FIG. 1, a refrigerator compartment and a vegetable compartment are provided in order from the top, and an ice making chamber and a small freezing chamber are provided side by side below the refrigerator chamber, and the bottom is provided. There is a freezer in the room.

The opening of the refrigerator compartment is closed by two left and right refrigerator compartment doors 11 and 12. The left end of the left refrigerating room door 11 is attached to the left end of the main body of the refrigerating room 10 by a hinge. The right end of the refrigerating room door 12 on the right side is attached to the right end of the main body of the refrigerating room 10 by a hinge. Due to this structure, the two left and right refrigerating room doors 11 and 12 can be opened by double doors. The vegetable room, the ice making room, the small freezing room, and the freezing room are closed by a pull-out vegetable room door 13, an ice making room door 14, a small freezing room door 15, and a freezing room door 16, respectively.

At least a part of these doors is provided with an operation unit 50 including a capacitance type sensor. The items that can be operated by the door on which the operation unit 50 is provided and the operation unit 50 are not limited, but in the case of the present embodiment, the operation unit 50a for opening the door is provided in the lower portion of the refrigerator compartment doors 11 and 12, respectively. Further, an operation unit 50b for controlling a cooling cycle or the like is provided at a central portion in the vertical direction of one of the refrigerating chamber doors 12. The control unit controls the refrigerating chamber 10 based on the operations of these operation units 50.

As an example of the cross-sectional structure of the door of the refrigerator 10, FIG. 2 shows a cross-sectional structure in the front-rear direction at the place where the operation unit 50 of the refrigerator compartment door 12 is provided. The outer shell of the refrigerator compartment door 12 is formed by combining a door front plate 30 provided on the outside of the refrigerator (front side of the refrigerator) and an inner plate 31 of the door provided on the inside of the refrigerator (rear side of the refrigerator) from the front and back. There is. The door front plate 30 is translucent. Generally, the door front plate 30 is colorless and transparent, and is made of glass having a thickness of, for example, about 3 mm. A transparent resin material such as transparent ABS resin or acrylic resin may be used. A heat insulating material 32 is provided between the door front plate 30 and the door inner plate 31. The material of the heat insulating material 32 is not limited. Examples of the material of the heat insulating material 32 include urethane foam, polystyrene foam, glass wool and the like. An operation unit 50 is provided between the door front plate 30 and the heat insulating material 32. Further, a metal film having a small parasitic capacitance, which will be described later, is provided between the door front plate 30 and the operation unit 50. The method of providing the metal film is not limited, but in the case of the present embodiment, the metal film is laminated as a part of the film 40, and the film 40 is provided between the door front plate 30 and the operation unit 50. There is. The operation unit 50 may be provided with a capacitance type sensor, and its structure is not limited. In the case of the present embodiment, as shown in FIG. 2, the operation unit 50 includes a first substrate 54 and electrodes 52 of a plurality of capacitance type sensors provided on the first substrate 54. Further, on the inside (rear side) of the first substrate 54, a second substrate 55 including a light source 56 such as a microcomputer 57 and an LED is provided. The microcomputer 57 detects a change in the capacitance of the electrode 52 of the capacitance type sensor and turns on the light source 56. The first substrate 54 and the second substrate 55 are electrically connected to each other via a connector 51 and a relay bundle wire 53, respectively. The light of the light source 56 passes through the hole 58 provided in the first substrate 54 and illuminates the film 40 on the outside of the refrigerator from the operation unit 50 from the inside of the refrigerator. As will be described later, since the film 40 is made of a translucent member, characters and the like printed on the film 40 can be seen from outside the refrigerator.

The capacitance type sensor of this embodiment is a self-capacitance type capacitance type sensor. When a conductor such as a human finger approaches or comes into contact with the outer part of the electrode 52 of the capacitance type sensor of the door front plate 30, a capacitance is generated between the conductor and the electrode 52 of the capacitance type sensor. The amount of charge generated and accumulated in the electrode 52 of the capacitance type sensor changes, and the microcomputer 57 detects the approach or contact of the conductor. In particular, it is desirable that the capacitance type sensor is a proximity sensor that detects that the conductor has approached the outer side portion of the electrode 52 of the capacitance type sensor of the door front plate 30. The degree of detectable approach is not limited, but for example, when the door front plate 30 approaches a place 10 to 20 cm away from the outside portion of the electrode 52 of the capacitive sensor in the direction perpendicular to the door front plate 30. Detectable. However, the capacitance type sensor may be a touch sensor that detects it only when the conductor comes into contact with the outer portion of the electrode 52 of the capacitance type sensor of the door front plate 30. Further, the capacitance type sensor may be capable of switching between a proximity mode that works as a proximity sensor and a touch mode that works as a touch sensor. Proximity sensors require higher sensitivity than touch sensors. The film 40 includes a sheet-shaped base material 41. The base material 41 has translucency, and it is more desirable that the base material 41 is colorless and transparent. The material of the base material 41 is not limited, but a synthetic resin is preferable, and polyethylene terephthalate is particularly preferable from the viewpoint of appearance quality. As shown in the figure, it is desirable that the inner surface of the base material 41 is provided with an uneven shape. Further, the printed layer 42 may be formed by printing characters or the like on the inner surface of the base material 41. Examples of the printing method include UV printing in which a pattern or the like drawn with ultraviolet curable ink is exposed to ultraviolet rays to instantly cure the pattern or the like.

A metal film having a small parasitic capacitance is laminated on the inside of the base 41 (inside the inside of the base 41 when the printing layer 42 is formed on the inside of the base 41). The small parasitic capacitance means that the parasitic capacitance is smaller than the parasitic capacitance of the substrate provided with the electrode 52 of the capacitance type sensor, or smaller than the parasitic capacitance of the door front plate 30. Further, when the parasitic capacitance is smaller than the parasitic capacitance of the substrate provided with the electrode 52 of the capacitance type sensor, the second substrate 54 provided with the electrode 52 of the capacitance type sensor is provided with the microcomputer 57 as in the present embodiment. When the substrate 55 is electrically connected, it means that it is smaller than the parasitic capacitance of the first substrate 54 in the connected state. Here, the parasitic capacitance of the substrate is the parasitic capacitance generated between the wiring pattern such as the ground arranged on the substrate and the metal of the electrode 52, or the element such as the microcomputer of the capacitance type sensor mounted on the substrate and the electrode 52. It is the sum of the parasitic capacitances that affect the electrode 52, such as the parasitic capacitances between the two, and means the parasitic capacitances of the entire substrate in a state where the wiring pattern and the elements are mounted on the substrate. The capacitance type sensor detects the capacitance generated between the electrode and the human finger, and the parasitic capacitance such as the parasitic capacitance of the substrate and the parasitic capacitance of the metal film is the capacitance type sensor. It is desirable that the size is small because it hinders the detection of capacitance by.

Various metal films having a small parasitic capacitance can be mentioned, but in the present embodiment, the discontinuous vapor deposition film 43 is adopted as an example of the metal film having a small parasitic capacitance. The discontinuous vapor deposition film 43 is a metal film that exhibits non-conductivity and has a small parasitic capacitance because the metal particles are not bonded to each other. The discontinuous vapor deposition film 43 is formed by a known metal vapor deposition method. When the term "metal vapor deposition method" is used, it includes not only the vacuum vapor deposition method but also sputtering and the like. The type of metal used for the discontinuous vapor deposition film 43 is not limited. However, in tin alloy, which is an alloy containing tin or tin, an oxide layer is formed around the metal particles by a known metal vapor deposition method, and a discontinuous vapor deposition film 43 is easily formed. The discontinuous vapor deposition film 43 has translucency. When the surface of the base material 41 inside the refrigerator is provided with an uneven shape, the discontinuous vapor deposition film 43 is also provided with an uneven shape. Assuming that the length of the refrigerating chamber door 12 between the concave and convex vertices of the discontinuous vapor deposition film 43 in the front-rear direction is the height of the concave-convex shape, the height of the concave-convex shape is about several μm to several mm.

The inner surface of the discontinuous vapor deposition film 43 may be covered with a sheet-shaped protective layer 45. The protective layer 45 is adhered to the discontinuous vapor deposition film 43 via an adhesive layer 44 containing an adhesive. The material of the protective layer 45 is not limited. However, when the heat insulating material 32 contains urethane foam (that is, one made of urethane foam or one in which another material is added to urethane foam), it is desirable that the protective layer 45 is made of polyvinyl chloride.

A light-transmitting colored layer 46 may be provided on the outside of the base material 41. The material and forming method of the colored layer 46 are not limited, but are formed by printing on the outer surface of the base material 41 by UV printing or the like. An adhesive layer 47 used for attaching the film 40 and the door front plate 30 may be formed on the outer surface of the colored layer 46. The adhesive layer 47 is translucent. It is desirable that the adhesive layer 47 is colorless and transparent in a solid state. The adhesive layer 47 is preferably made of a UV curing agent (a resin that undergoes radical polymerization or cationic polymerization when irradiated with ultraviolet rays and cures). When the adhesive layer 47 is made of a UV curing agent, the door front plate 30 and the film 40 are attached by applying the surface of the film 40 on the adhesive layer 47 side to the door front plate 30 and irradiating ultraviolet rays from the door front plate 30 side. Can be glued. Further, a logo or the like may be printed on the inner surface of the door front plate 30 by a method such as silk screen.

The layers of the film 40 are in close contact with each other. Such a film 40 is provided on the entire rear side of the door front plate 30 of the refrigerator compartment door 12, for example.

An example of the manufacturing method of the refrigerating chamber door 12 having the above structure is shown. First, each layer is laminated on the base material 41 by the method exemplified above to produce the film 40. Next, the film 40 is adhered to the door front plate 30. Next, the door front plate 30 to which the film 40 is attached and the door inner plate 31 are combined by fitting them into the door cap. Next, the operation unit 50 is slid from the opening provided in the door cap or the like and inserted into the refrigerator compartment door 12, the operation unit 50 is fixed in the refrigerator compartment door 12, and then the opening is closed. .. Finally, the heat insulating material is injected into the space between the door front plate 30 and the door inner plate 31 through the holes formed in the door front plate 30 or the door inner plate 31. In addition, a storage container for storing stored items is fixed to the inner surface of the door inner plate 31. The refrigerator compartment door 12 completed in this way is attached to the main body of the refrigerator 10 with a hinge or the like.

In the refrigerator 10 of the present embodiment having the above structure, in the refrigerator compartment door 12, the front part of the operation unit 50 is between the door front plate 30 and the operation unit 50, and the part other than the front part of the operation unit 50 is the door. Since the metal discontinuous vapor deposition film 43 is provided between the front plate 30 and the heat insulating material 32, the entire refrigerator door 12 has a metallic luster in appearance. Moreover, since the parasitic capacitance of the discontinuous vapor deposition film 43 between the door front plate 30 and the electrode 52 of the capacitance type sensor is small, when a conductor such as a human finger approaches or comes into contact with the door front plate 30, it is static. The capacitance sensor can detect this without being hindered by the discontinuous vapor deposition film 43. Therefore, the operability of the capacitance type sensor is good.

If the parasitic capacitance of the metal film such as the discontinuous vapor deposition film 43 is smaller than the parasitic capacitance of the substrate provided with the electrode 52 of the capacitance type sensor, the design is made by changing the uneven shape of the metal film or the thickness of the metal film. The same substrate can be used even if the above is changed. Therefore, it is not necessary to change the substrate every time the design is changed, and the design variation of the door can be easily increased.

When the parasitic capacitance of the metal film such as the discontinuous vapor deposition film 43 is smaller than the parasitic capacitance of the door front plate 30, among the door front plate 30 and the metal film that affect the electrode 52 of the capacitance type sensor, By arranging the door front plate 30 having a large parasitic capacitance at a position far from the electrode 52 of the capacitance type sensor and suppressing the influence of the parasitic capacitance, the detection by the capacitance sensor can be performed accurately.

In particular, when the capacitance type sensor is a proximity sensor, it is necessary that the sensitivity of the capacitance type sensor is high. In the present embodiment, since the metal between the door front plate 30 and the electrode 52 of the capacitance type sensor is a discontinuous vapor deposition film 43 having a small parasitic capacitance, the sensitivity required for a proximity sensor is maintained.

Here, if the discontinuous vapor deposition film 43 is made of tin or a tin alloy, the discontinuous vapor deposition film 43 is easy to manufacture, and the parasitic capacitance of the discontinuous vapor deposition film 43 is small, so that the operability of the capacitance type sensor is small. Becomes good. Further, it is difficult to deposit some metals such as tin or tin alloy on the glass door front plate 30. However, in the present embodiment, the discontinuous thin-film deposition film 43 is not directly laminated on the back surface of the door front plate 30, but is provided between the door front plate 30 and the electrode 52 of the capacitive sensor. Even if it is a metal that is difficult to deposit on the glass door front plate 30 because it is laminated on the base material 41 of 40, there is a discontinuity between the door front plate 30 and the electrode 52 of the capacitance type sensor. It can be provided as a vapor deposition film 43.

Further, the discontinuous vapor deposition film 43 is not directly laminated on the back surface of the door front plate 30, but is a base material of the film 40 provided between the door front plate 30 and the electrode 52 of the capacitance type sensor. Since it is laminated on 41, it is possible to increase the variation in the appearance of the door from the outside of the refrigerator by changing the detailed structure of the film 40.

For example, when the discontinuous vapor deposition film 43 inside the refrigerator of the base material 41 is provided with an uneven shape, the base material 41 and the door front plate 30 are translucent, so that the uneven shape with metallic luster from the outside of the refrigerator can be obtained. appear. Then, the refrigerator 10 can be given a three-dimensional effect by the visual effect of the uneven shape.

Further, when the discontinuous vapor deposition film 43 is laminated on the inner surface of the base material 41 and the light-transmitting colored layer 46 is laminated on the outer surface of the base material 41, when viewed from the outside. The discontinuous vapor deposition film 43 can be seen through the back side of the colored layer 46, and the door has a gloss derived from metallic luster and appears to be colored.

Further, when a fluid heat insulating material is injected between the door front plate 30 and the door inner plate 31 in the door manufacturing process, the heat insulating material and the discontinuous vapor deposition film 43 come into contact with each other, and then the heat insulating material shrinks. , The discontinuous vapor deposition film 43 may be wrinkled. However, when the protective layer 45 is provided inside the discontinuous vapor deposition film 43, it is possible to prevent the heat insulating material from coming into contact with the discontinuous vapor deposition film 43, and the discontinuous vapor deposition film 43 may be wrinkled. Can be prevented. Further, when the heat insulating material 32 contains urethane foam and the protective layer 45 is made of polyvinyl chloride, the adhesion between the heat insulating material 32 and the film 40 is improved.

Further, if the film 40 including the discontinuous vapor deposition film 43 is provided on the entire rear side (inside of the refrigerator) of the door front plate 30 of the refrigerator compartment door 12, the appearance of the entire refrigerator compartment door 12 is excellent. Further, if the film 40 provided with the discontinuous vapor deposition film 43 is provided behind the door front plates of all the doors of the refrigerator 10, the appearance of the refrigerator 10 as a whole becomes excellent.

Various changes can be made to the above embodiments without departing from the gist of the invention. Examples of changes are listed below.

(Change example 1)
When a film is provided between the door front plate 30 and the operation unit 50, the film may include at least a sheet-like base material and a metal film laminated therewith with a small parasitic capacitance. Therefore, the film may be composed of only a base material and a metal film having a small parasitic capacitance, or may have a layer different from the layer described in the above embodiment. Further, the metal film having a small parasitic capacitance may be provided on the outside of the base material.

(Change example 2)
The metal film having a small parasitic capacitance may be provided at least on the door provided with the capacitance type sensor. Therefore, for example, a door provided with a capacitance type sensor is provided with a film having a metal film having a small parasitic capacitance, and other doors are provided with a metal having a large parasitic capacitance (for example, aluminum or an aluminum alloy which is an alloy containing aluminum). ) May be provided.

(Change example 3)
When a metal film having a concave-convex shape and a small parasitic capacitance (here, a discontinuous vapor deposition film is used as an example) is provided on a plurality of (for example, all) doors, some of them are used. , The height of the uneven shape provided on the discontinuous vapor deposition film may be different from that of other doors. That is, the height of the uneven shape provided on the discontinuous vapor deposition film may be different between some doors and other doors. For example, in the refrigerating room doors 11 and 12, which are doors at the height of human eyes, the height of the uneven shape of the discontinuous vapor deposition film is low, and in the other doors, the height of the uneven shape is higher than that. You may be.

Here, in order to give a three-dimensional effect to the door, it is desirable that the height of the uneven shape of the discontinuous vapor deposition film is high. However, if the height of the uneven shape is high, interference fringes of light are likely to occur, which may impair the aesthetic appearance. Here, interference fringes are likely to occur when a person views the door from its normal direction. That is, interference fringes are likely to occur at the height of human eyes.

Therefore, as in the above example, if the height of the uneven shape of the discontinuous vapor deposition film is low in the refrigerating chamber doors 11 and 12, which are doors at the height of human eyes, the risk of humans visually recognizing interference fringes is reduced. Will be done. If the height of the uneven shape of the other doors is high, the refrigerator as a whole has a three-dimensional effect.

Further, the door may have a plurality of regions having different heights of the uneven shape provided on the discontinuous vapor deposition film. That is, a plurality of regions having different heights of the uneven shape of the discontinuous vapor deposition film may be provided in one door. For example, in the refrigerating room door 12, the height of the uneven shape of the discontinuous vapor deposition film is low at the center of the door and the lower part of the door (for example, the lower two-thirds of the door) at the height of the human eye. At the upper part of the door (for example, the upper 1/3 portion of the door) located at a position higher than the height of the door, the height of the uneven shape of the discontinuous vapor deposition film may be higher than that. Also in this case, the possibility that a person visually recognizes the interference fringes is reduced, and the refrigerator as a whole has a three-dimensional effect.

(Change example 4)
FIG. 3 shows another example of a metal film having a parasitic capacitance smaller than the parasitic capacitance of the first substrate 54 including the electrode 52 of the capacitance type sensor.

The film 140a of FIG. 3 is provided between the door front plate 30 and the operation unit 50 like the above film 40. In this film 140a, a plurality of dot-shaped metal portions 143a are arranged on one side of the sheet-shaped base material 141 to form a metal film. The material of the dot-shaped metal portion 143a is not limited, but may be, for example, aluminum or an aluminum alloy. It is desirable that the diameter p of one dot-shaped metal portion 143a is 500 μm or less, and the distance q between the two nearest dot-shaped metal portions 143a is 100 μm or less. Further, it is more desirable that the ratio of the total area of all the dot-shaped metal portions 143a to the area of the base material 141 is 80% or more. Such a metal film can be produced, for example, by using a known photographic technique. In addition to the base material 141 and the metal film, the film 140a may be provided with a coloring layer, a protective layer, or the like as in the film 40 of the above embodiment.

Since the diameter p of one dot-shaped metal portion 143a is as small as 500 μm or less and the dot-shaped metal portions 143a are not bonded to each other, this metal film exhibits non-conductivity and its parasitic capacitance is a capacitance type sensor. It is smaller than the parasitic capacitance of the first substrate 54 including the electrode 52 of the above. Therefore, as in the case of the above embodiment, when a conductor such as a human finger approaches or comes into contact with the door front plate 30, the capacitance type sensor can detect it without the metal film hindering it. In the case of a metal film in which the plurality of dot-shaped metal portions 143a are lined up, even a metal such as aluminum or an aluminum alloy, which tends to have a large parasitic capacitance when the metal particles are continuous, can be attached to the door front plate 30. It can be used as a material for a metal film having a small parasitic capacitance provided between the operation unit 50 and the operation unit 50.

Further, since the distance q between the two nearest dot-shaped metal portions 143a is as narrow as 100 μm or less and the total area of all the dot-shaped metal portions 143a is large, the metal may be dot-shaped by human vision. do not know. Therefore, the refrigerating room door 12 has a metallic luster in appearance as in the case of the above embodiment.

Further, the film 140b of FIG. 4 is also provided between the door front plate 30 and the operation unit 50 like the above film 40. In this film 140b, a plurality of strip-shaped metal portions 143b are arranged in a stripe shape on one side of a sheet-shaped base material 141 to form a metal film. The material of the strip-shaped metal portion 143b is not limited, but may be, for example, aluminum or an aluminum alloy. It is desirable that the width r of one strip-shaped metal portion 143b is 500 μm or less, and the distance s between two adjacent strip-shaped metal portions 143b is 100 μm or less. Further, it is more desirable that the ratio of the total area of all the strip-shaped metal portions 143b to the area of the base material 141 is 80% or more. Such a metal film can be produced, for example, by using a known photographic technique. In addition to the base material 141 and the metal film, the film 140b may be provided with a coloring layer, a protective layer, or the like as in the film 40 of the above embodiment.

The metal film of FIG. 4 does not interfere with the detection of the conductor by the capacitance type sensor, and also makes the appearance of the refrigerator compartment door 12 excellent.

(Change example 5)
Capacitance when a metal film having a parasitic capacitance smaller than the parasitic capacitance of the first substrate 54 including the electrode 52 of the capacitance sensor is provided at least in the front portion of the electrode 52 of the capacitance sensor. A metal layer having a parasitic capacitance larger than that of the metal film may be provided on a portion other than the front of the electrode 52 of the type sensor.

An example thereof is shown in FIG. The same reference numerals are given to the parts common to FIGS. 2 and 5. In this modified example, a metal layer 243b having a larger parasitic capacitance is laminated in front of a metal film 243a having a parasitic capacitance smaller than the parasitic capacitance of the first substrate 54 provided with the electrode 52 of the capacitance type sensor. .. Both the metal film 243a and the metal layer 243b are provided on the rear side of the door front plate 30 over a wide area (preferably the entire rear side of the door front plate 30). However, the front portion of the electrode 52 of the capacitance type sensor of the metal layer 243b is cut out. The portion to be cut out may be only the front portion of the electrode 52 of the capacitance type sensor, or the front portion of the electrode 52 of the capacitance type sensor and its peripheral portion (for example, the entire front portion of the operation unit 50). The material of the metal layer 243b is not limited. Although the layer corresponding to the print layer 42 of the above embodiment is omitted in FIG. 5, the print layer 42 may actually exist.

In the case of this modification, a layer of a metal (for example, aluminum or aluminum alloy) having a large parasitic capacitance but being preferable in appearance is provided as a metal layer 243b in a portion other than the front of the electrode 52 of the capacitance type sensor, and the refrigerating chamber door 12 Can be made excellent in appearance. On the other hand, the front portion of the electrode 52 of the capacitance type sensor is not provided with the metal layer 243b having a large parasitic capacitance, and only the metal film 243a having a small parasitic capacitance is provided. When a conductor such as a finger approaches or comes into contact with the conductor, it can be detected by the capacitance type sensor without being hindered by the metal layer 243b.

Another example is shown in FIG. The same reference numerals are given to the parts common to FIGS. 2 and 6. In this modification, the metal film 343a having a parasitic capacitance smaller than the parasitic capacitance of the first substrate 54 provided with the electrode 52 of the capacitance type sensor and the metal layer 343b having a parasitic capacitance larger than that of the metal film 343a are on the same plane. It is provided in. Specifically, the metal film 343a having a small parasitic capacitance may be only the front part of the electrode 52 of the capacitance type sensor (the front part of the electrode 52 of the capacitance type sensor may be only, or the front part of the electrode 52 of the capacitance type sensor. A portion in which the portion and the peripheral portion thereof are combined may be provided), and a metal layer 343b having a larger parasitic capacitance than the metal film 343a is provided in the other portion. The metal film 343a and the metal layer 343b are on the same surface. That is, the portion of the metal film 343a and the portion of the metal layer 343b are separated on the same plane.

Also in the case of this modification, a layer of a metal (for example, aluminum or aluminum alloy) having a large parasitic capacitance but being preferable in appearance is provided as a metal layer 343b in a portion other than the front of the electrode 52 of the capacitance type sensor, and the refrigerating chamber door is provided. 12 can be made excellent in appearance. On the other hand, the front portion of the electrode 52 of the capacitance type sensor is not provided with the metal layer 343b having a large parasitic capacitance, and only the metal film 343a having a small parasitic capacitance is provided. When a conductor such as a finger approaches or comes into contact with the conductor, it can be detected by the capacitance type sensor without being hindered by the metal layer 343b. Further, the amount of the metal film 343a used can be reduced as compared with the case of FIG.

Since the parasitic capacitance differs depending on the thickness of the same metal, the metal film 343a and the metal layer 343b may be made of the same metal and have different thicknesses.

In addition, in FIGS. 5 and 6, irregularities are not formed on the metal film or the like having a small parasitic capacitance, but irregularities may be formed as in the embodiment of FIG.

(Change example 6)
Since there is an air layer around the substrate of the operation unit 50 (first substrate 54 and second substrate 55), if the low temperature in the storage chamber is transmitted to the substrate, the substrate will condense and the operation unit 50 will malfunction. There is a risk. Therefore, some measures may be taken to prevent dew condensation on the substrate. Examples of such ingenuity are shown in FIGS. 7 to 9. In FIGS. 7 to 9, the same parts as those in the other figures are designated by the same reference numerals.

In the example of FIG. 7, the vacuum heat insulating panel 432 is provided inside the chamber of the operation unit 50. The vacuum heat insulating panel 432 is a box body filled with glass wool or the like and then exhausted. It is desirable that the thickness of the vacuum insulation panel 432 in the front-rear direction is 20 mm or more. In the case of this example, since the vacuum heat insulating panel 432 is provided inside the operation unit 50, the low temperature in the storage chamber is less likely to be transmitted to the substrate of the operation unit 50, and the substrate is less likely to condense.

Another example is shown in FIG. In this example, a metal member 532 having good thermal conductivity is arranged in a portion of the door that houses the operation portion 50. Specifically, a metal member 532 (for example, a metal foil such as an aluminum foil or a metal plate) is provided so as to be in contact with the inner surface of the operation unit 50. The metal member 532 further extends toward the outside of the refrigerator so as to wrap the operation portion 50 from the inside of the refrigerator. In the case of this example, the heat on the outside of the refrigerator is transferred to the metal member 532, and the surface on the inside of the operation unit 50 in contact with the metal member 532 is kept at a relatively high temperature. Therefore, the temperature of the substrate in the operation unit 50 is unlikely to be low, and the substrate is less likely to condense.

Another example is shown in FIG. In this example, the door is provided with a heater 601. The place where the heater 601 is provided is not limited, but for example, the rotary partition body 602 (provided on the right side of the left refrigerating room door 11 and in close contact with the left side of the right refrigerating room door 12 in the closed state, thereby. It is a place near the inside of the left and right refrigerating room doors 11 and 12) and the operation unit 50 inside the door. In this example, the heat of the heater 601 keeps the substrate at a relatively high temperature, so that the substrate is less likely to condense. When the heater 601 is separated from the operation unit 50, a metal member (for example, a metal foil such as an aluminum foil or a metal plate) may be provided from the heater 601 to the operation unit 50. As a result, the heat of the heater 601 is effectively transferred to the substrate of the operation unit 50, and the substrate of the operation unit 50 is less likely to condense dew. When the heater 601 and the operation unit 50 are close to each other, such a metal member may be omitted.

When there is an outlet for cold air into the storage chamber behind the operation unit 50, the temperature of the operation unit 50 tends to be low, so the above measures are particularly effective. Two or more configurations out of the above three examples may be combined.

Due to the synergistic effect of preventing dew condensation on the substrate and providing a metal film having a small parasitic capacitance between the door front plate 30 and the electrode 52 of the capacitance type sensor, the operation unit 50 is There are few malfunctions and the operability is improved.

(Change example 7)
The refrigerator door is opened and closed many times, and each time it is opened and closed, it is shocked. Therefore, the first substrate 54 of the operation unit 50 may be displaced from the initial position, and the electrode 52 of the capacitance type sensor may be displaced with respect to the film 40. In that case, even if the button is displayed on the film 40, the position of the button display and the position of the electrode 52 of the capacitive sensor deviate from each other, so that even if a human finger or the like approaches or touches the button display, it is static. The capacitance type sensor may not respond. Therefore, as a countermeasure, a device may be devised to prevent the electrode 52 of the capacitance type sensor from being displaced.

An example of such a device is shown in FIG. In this example, the operation unit 50 and the electrode 52 of the capacitance type sensor provided therein are pressed against the door front plate 30 and the film 40 so as not to shift with respect to the film 40. Although the structure for pressing is not limited, the elastic means 703 is used in the example of FIG. In this example, the storage member 701 is fixed inside the refrigerator compartment door 12. The storage member 701 is fixed to the inside of the refrigerating room door 12 (for example, a door cap 702 provided at the upper, lower, left, and right ends of the refrigerating room door 12 and integrating the door front plate 30 and the door inner plate 31). There is. The operation unit 50 is surrounded by the storage member 701 inside the refrigerator compartment door 12.

Then, one end of the elastic means 703 such as a spring or rubber is fixed to the storage member 701, and the other end of the elastic means 703 is fixed to a part of the operation portion 50. Then, the operation unit 50 and the electrode 52 of the capacitance type sensor fixed to the operation unit 50 are pressed against the door front plate 30 and the film 40 by the force of the elastic means 703.

As a result, the electrode 52 of the capacitance type sensor provided in the operation unit 50 is less likely to shift with respect to the film 40, and when a human finger or the like approaches or touches the button display, the capacitance corresponding to the button is obtained. The formula sensor will respond correctly.

Further, the electrode 52 of the capacitance type sensor may be pressed toward the door front plate 30 and the film 40 by a means different from the elastic means 703. For example, the operation unit 50 is inserted into the refrigerator compartment door 12. An opening is provided in the door cap 702, and a guide means such as a rail for moving the operation unit 50 may be provided from the opening to the fixed position of the operation unit 50 inside the refrigerator compartment door 12. .. Then, when the operation unit 50 is moved along the guide means, the operation unit 50 is gradually pushed toward the door front plate 30, and when it reaches the fixed position of the operation unit 50, it is pressed against the film 40. It may be configured.

In addition to the above modification examples, various modifications, substitutions, omissions, etc. can be made without departing from the gist of the invention. The above is an example, and the scope of the invention is not limited to this. The above embodiments and modifications thereof are included in the inventions described in the claims and the equivalent scope thereof.

10 ... Refrigerator, 11, 12 ... Refrigerator door, 13 ... Vegetable room door, 14 ... Ice making room door, 15 ... Small freezer door, 16 ... Freezer door, 30 ... Door front plate, 31 ... Door inner plate, 32 ... Insulation material, 40 ... film, 41 ... base material, 42 ... printing layer, 43 ... discontinuous vapor deposition film, 44 ... adhesive layer, 45 ... protective layer, 46 ... colored layer, 47 ... adhesive layer, 50, 50a, 50b ... Operation unit, 51 ... Connector, 52 ... Capacitive sensor electrode, 53 ... Relay bundle wire, 54 ... First board, 55 ... Second board, 56 ... Light source, 57 ... Microcomputer, 58 ... Hole, 140a ... Film, 140b ... film, 141 ... base material, 143a ... dot-shaped metal part, 143b ... strip-shaped metal part,
243a ... metal film, 243b ... metal layer, 343a ... metal film, 343b ... metal layer,
432 ... Vacuum insulation panel, 532 ... Metal member, 601 ... Heater, 602 ... Rotating partition,
701 ... Storage member, 702 ... Door cap, 703 ... Elastic means

Claims (16)

In a refrigerator with a door that opens and closes the opening of the storage room
The door includes a door front plate provided on the outside of the refrigerator, a door inner plate provided on the inside of the refrigerator, a heat insulating material provided between the door front plate and the door inner plate, and the door front plate. An electrode of a capacitance type sensor provided between the door and the heat insulating material, and a translucent metal-containing layer provided between the door front plate and the electrode of the capacitance type sensor. Prepare,
A refrigerator characterized in that a light-transmitting colored layer is provided between the door front plate and the metal-containing layer on the outside of the electrode of the capacitance type sensor. The refrigerator according to claim 1, wherein the parasitic capacitance of the metal-containing layer is smaller than the parasitic capacitance of the substrate provided with the electrode of the capacitance type sensor or the parasitic capacitance of the door front plate. The refrigerator according to claim 1 or 2, wherein the metal-containing layer is a discontinuous vapor-deposited film. Any of claims 1 to 3, wherein the metal-containing layer is laminated on a translucent sheet-like base material provided between the door front plate and the electrode of the capacitance type sensor. The refrigerator according to item 1. The refrigerator according to any one of claims 1 to 4, wherein the metal-containing layer is made of tin or a tin alloy. The refrigerator according to any one of claims 1 to 5, wherein the metal-containing layer is provided with an uneven shape. The refrigerator according to claim 4, wherein the base material has the metal-containing layer laminated on the inside of the refrigerator and a colored layer having translucency on the outside of the refrigerator. The refrigerator according to claim 4, wherein the metal-containing layer is laminated on the inside of the base material, and a protective layer is laminated on the inside of the metal-containing layer. The refrigerator according to claim 8, wherein the protective layer is made of polyvinyl chloride and the heat insulating material contains urethane foam. Equipped with multiple doors
The refrigerator according to claim 6, wherein some of the doors of the plurality of doors have a height of an uneven shape provided on the metal-containing layer different from that of the other doors. The refrigerator according to claim 6, wherein the door has a plurality of regions provided on the metal-containing layer having different heights of the uneven shape. The refrigerator according to any one of claims 1 to 11, wherein the capacitance type sensor is a proximity sensor that detects a conductor approaching the door front plate. The refrigerator according to any one of claims 1 to 12 , wherein a metal layer having a parasitic capacitance larger than that of the metal-containing layer is provided in a portion other than the front of the electrode of the capacitance type sensor. The refrigerator according to claim 13, wherein the metal-containing layer and the metal layer are provided on the same plane. The refrigerator according to any one of claims 1 to 12, wherein the metal-containing layer is formed by arranging a plurality of dot-shaped metal portions. The refrigerator according to any one of claims 1 to 12, wherein the metal-containing layer is formed by arranging a plurality of strip-shaped metal portions in a striped pattern.

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