JP2023059833A - Dial unit, input system, dial component, and dial exterior body - Google Patents

Abstract

To provide a dial on an input surface of a touch panel while securing designability of an input system.SOLUTION: A dial unit 1 is provided on an input surface 8a of a capacitance type touch panel 8 for inputting rotation information to the touch panel 8. The dial unit has: a supporting part 5 fixed on the input surface 8a; a dial exterior body 3 rotatably supported by the supporting part 5 and provided with a through hole 36; and an electrode 4 fixed to the dial exterior body 3 and detected by the input surface 8a of the touch panel 8. At least a part of the input surface 8a can be viewed through the through hole 36. The dial exterior body 3 includes an insulating material. The dial exterior body 3 covers the electrode 4 on the input surface 8a.SELECTED DRAWING: Figure 3a

Description

TECHNICAL FIELD The present disclosure relates to dial units, input systems, dial components and dial jackets.

At present, a capacitive touch panel is widely known as an input means. It is also widely known to display information on the input surface of a touch panel. For example, the touch panel is superimposed on the display device to form a display device with a touch panel. According to the display device with a touch panel, information can be displayed on the input surface of the touch panel by the display device. A user of a display device with a touch panel can input information by referring to the information displayed on the input surface and touching the input surface.

It is also known to provide a dial switch on a touch panel so that a user can perform intuitive operations without looking at the input surface of the touch panel (eg, Patent Document 1). Patent Document 1 discloses a dial switch formed by rotatably mounting a rotating portion to a fixed portion. In the dial switch of Patent Document 1, rotation information can be input to the touch panel by fixing the fixed portion on the touch panel and rotating the rotating portion with respect to the fixed portion.

JP 2019-185427 A

When forming an input system by providing a dial on the input surface of a touch panel, it is required to provide the dial on the input surface of the touch panel while ensuring designability of the input system.

The present disclosure has been made in consideration of such points, and an object thereof is to provide a dial on the input surface of the touch panel while ensuring designability of the input surface of the touch panel.

A first aspect of the present disclosure is a dial unit provided on an input surface of a capacitive touch panel for inputting rotation information to the touch panel,
a support fixed on the input surface;
a dial exterior body rotatably supported by the support portion and provided with a through hole;
an electrode fixed to the dial outer body and detected on the input surface of the touch panel;
at least a portion of the input surface is visible through the through hole;
The dial outer body includes an insulating material,
The dial outer body is a dial unit covering the electrodes on the input surface.

A second aspect of the present disclosure is the dial unit according to the first aspect described above, in which the dial outer body moves in a direction horizontal to the input surface as at least a part of the outer surface of the dial outer body approaches the input surface. and/or the width of the through-hole in the direction horizontal to the input surface is reduced as at least a portion of the inner surface of the dial outer body approaches the input surface. It may be slanted.

A third aspect of the present disclosure is the dial unit according to the above-described second aspect, wherein the input surface is visible through the through hole from any direction at an angle of 27° or less with respect to the normal to the input surface. The area of the upper region may be 80% or more of the area of the region on the input surface that is visible through the through hole from a direction perpendicular to the input surface.

A fourth aspect of the present disclosure is the dial unit according to each of the first aspect to the third aspect described above, wherein the electrodes include a detection electrode portion that is detected on the input surface, a detection electrode portion that is detected on the input surface and the A parasitic capacitance generating electrode portion separated from the sensing electrode portion and a connecting portion coupling the sensing electrode portion and the parasitic capacitance generating electrode portion may be provided.

A fifth aspect of the present disclosure is the dial unit according to the fourth aspect described above, wherein the electrodes having the detection electrode portion, the parasitic capacitance generating electrode portion, and the connection portion are formed by an integral metal plate. may be formed.

A sixth aspect of the present disclosure is the dial unit according to the above-described fourth aspect or the above-described fifth aspect, wherein at least a portion of the outer surface of the dial outer body becomes horizontal to the input surface as it approaches the input surface. inclined to expand the width of the dial outer body in the direction,
In a radial direction perpendicular to the axis of rotation of the dial outer body with respect to the support, the sensing electrode portion is located on the opposite side of the connecting portion to the axis of rotation,
In the radial direction, the parasitic capacitance generating electrode portion may be positioned on the rotation axis side of the connecting portion.

A seventh aspect of the present disclosure is the dial unit according to the above-described fourth aspect or the above-described fifth aspect, wherein at least a part of the inner surface of the dial outer body is horizontal to the input surface as it approaches the input surface. inclined to reduce the width of the through hole in the direction of
In a radial direction perpendicular to the rotation axis of the dial outer body rotating with respect to the support part, the detection electrode part is positioned on the rotation axis side of the connecting part,
In the radial direction, the parasitic capacitance generating electrode portion may be located on the opposite side of the connecting portion from the rotation axis.

According to an eighth aspect of the present disclosure, the dial unit according to each of the above-described first aspect to the above-described seventh aspect may further include a transparent portion at least part of which is arranged inside the through hole. .

According to a ninth aspect of the present disclosure, in the dial unit according to the eighth aspect described above, the transparent portion may contain a resin material, and the transparent portion may have a refractive index greater than 1.4 and less than 1.6.

A tenth aspect of the present disclosure is the dial unit according to the above-described eighth aspect or the above-described ninth aspect, wherein the transparent portion is spaced apart from the dial outer body,
The dial outer body may be relatively movable with respect to the transparent portion.

According to an eleventh aspect of the present disclosure, in the dial unit according to the above eighth aspect or the above ninth aspect, the transparent portion may be fixed to the dial outer body.

According to a twelfth aspect of the present disclosure, the dial unit according to each of the first aspect to the eleventh aspect described above may further include a decorative layer covering at least a portion of the dial outer body.

A thirteenth aspect of the present disclosure is the dial unit according to the above-described twelfth aspect, wherein the decorative layer includes a decorative layer inner surface portion that covers the inner surface of the dial outer body, and a decorative layer inner surface portion that covers the outer surface of the dial outer body. Including a decorative layer outer surface portion,
The color of the inner surface portion of the decorative layer may be different from the color of the outer surface portion of the decorative layer.

A fourteenth aspect of the present disclosure is the dial unit according to the above-described thirteenth aspect, wherein the value of the lightness L ^* in the L ^* a ^* b ^* color system of the decorative layer inner surface portion is the value of the decorative layer outer surface portion may be greater than the value of lightness L ^* in the L ^* a ^* b ^* color system.

A fifteenth aspect of the present disclosure is the dial unit according to the above-described thirteenth aspect, wherein the value of L ^* a*b*lightness L ^* in the L*a ^* b ^* color system of the decorative layer inner surface portion is the value of the decorative layer outer surface portion may be smaller than the value of lightness L ^* in the L ^* a ^* b ^* color system.

A sixteenth aspect of the present disclosure is a dial unit provided on an input surface of a capacitive touch panel for inputting rotation information to the touch panel,
a support fixed on the input surface;
a dial exterior body rotatably supported by the support portion and provided with a through hole;
an electrode fixed to the dial outer body and detected on the input surface of the touch panel;
at least a portion of the input surface is visible through the through hole;
The dial unit further comprises a transparent part at least partly arranged inside the through hole.

A seventeenth aspect of the present disclosure is a dial unit laminated on a capacitive touch panel,
a support fixed on the touch panel;
a dial outer body rotatably supported by the support;
an electrode that is rotatable in conjunction with the rotation of the dial outer body and generates a capacitance,
The dial outer body includes an insulating material,
The dial unit, wherein the dial outer body covers the electrodes on the touch panel.

An eighteenth aspect of the present disclosure is an input system comprising a dial unit according to each of the above-described first to sixteenth aspects, and the touch panel.

A nineteenth aspect of the present disclosure is the input system according to the eighteenth aspect described above, wherein a direction in which the luminance of the input surface is a half value when viewed from a direction perpendicular to the input surface; a perpendicular line to the input surface; is defined as a half-value width angle, the area of the region on the input surface that is visible through the through-hole from any direction in which the angle formed with the normal to the input surface is equal to or less than the half-value width angle is It may be 80% or more of the area of the region on the input surface that is visible through the through hole from a direction perpendicular to the input surface.

A twentieth aspect of the present disclosure is the input system according to the above-described eighteenth aspect or the above-described eighteenth aspect, wherein the touch panel includes a body portion having an installation surface on which the dial unit is provided, and the and a decorative sheet provided in an area other than the area in which the dial unit is provided.

A twenty-first aspect of the present disclosure is an input system including a capacitive touch panel and a dial unit provided on an input surface of the touch panel for inputting rotation information to the touch panel,
The dial unit includes a support portion fixed on the input surface of the touch panel, a dial outer body rotatably supported by the support portion, and a dial outer body fixed to the dial outer body and detected on the input surface of the touch panel. and an electrode that is
The touch panel is an input system that includes a body portion having an installation surface on which the dial unit is provided, and a decorative sheet provided on an area of the installation surface other than the area on which the dial unit is provided.

A twenty-second aspect of the present disclosure is a dial component of a dial unit provided on an input surface of a capacitive touch panel for inputting rotation information to the touch panel,
a dial outer body rotatably supported by a support portion fixed on the input surface and provided with a through hole;
an electrode fixed to the dial outer body and detected on the input surface of the touch panel;
at least a portion of the input surface is visible through the through hole;
The dial outer body includes an insulating material,
The dial outer body is a dial component covering the electrodes on the input surface.

A 23rd aspect of the present disclosure is the dial component according to the 22nd aspect described above, in which at least a part of the outer surface of the dial outer body moves toward the input surface in a direction horizontal to the input surface. slanted to increase the width and/or slanted to reduce the width of the through-hole in the direction horizontal to the input surface as at least a portion of the inner surface of the dial outer body approaches the input surface You may have

A twenty-fourth aspect of the present disclosure is a dial exterior body of a dial unit that is provided on an input surface of a capacitive touch panel and inputs rotation information to the touch panel,
The dial outer body is rotatably supported by a support fixed on the input surface, an electrode to be detected on the input surface of the touch panel is fixed to the dial outer body, and the dial outer body is penetrated. holes are provided,
at least a portion of the input surface is visible through the through hole;
At least part of the outer surface of the dial outer body is inclined so as to increase the width of the dial outer body in the direction horizontal to the input surface as it approaches the input surface, and/or the inner surface of the dial outer body. at least part of is inclined so as to reduce the width of the through-hole in the horizontal direction to the input surface as it approaches the input surface.

According to the present disclosure, the dial can be provided on the input surface of the touch panel while ensuring the design of the input system.

FIG. 1 is a perspective view showing an input system according to the first embodiment. FIG. FIG. 2 is a top view showing the input system according to the first embodiment. FIG. 3a is a partial cross-sectional view showing a portion of the cross section taken along line IIIa--IIIa of FIG. FIG. 3b is a partial cross-sectional view showing a part of the cross section taken along line IIIb--IIIb of FIG. FIG. 4 is a perspective view showing the dial outer body according to the first embodiment. FIG. 5 is a perspective view showing electrodes according to the first embodiment. FIG. 6 is a cross-sectional view showing a dial unit provided with various dial outer bodies having different forms of inner inclined surfaces. FIG. 7a is a cross-sectional view showing an example of an input system according to the second embodiment. FIG. 7b is a cross-sectional view showing an example of the input system according to the second embodiment. FIG. 8 is a cross-sectional view showing an example of an input system according to the third embodiment. FIG. 9 is a cross-sectional view showing another example of the input system according to the third embodiment. FIG. 10a is a cross-sectional view showing another example of the input system according to the third embodiment. FIG. 10b is a cross-sectional view showing an example of an input system according to the third embodiment; FIG. 11 is a cross-sectional view showing an input system according to the fourth embodiment. 12 is a cross-sectional view showing an input system according to Modification 1. FIG. 13 is a top view showing a dial top cover according to Modification 1. FIG. FIG. 14 is a cross-sectional view showing an input system according to Modification 2. As shown in FIG. FIG. 15 is a cross-sectional view showing an input system according to Modification 2. As shown in FIG. FIG. 16 is a cross-sectional view showing an input system according to Modification 2. As shown in FIG. 17 is a top view showing an example of a dial outer body according to Modification 3. FIG. FIG. 18 is a side view showing an example of a dial outer body according to Modification 3. FIG. 19 is a side view showing an example of a dial outer body according to Modification 3. FIG. FIG. 20 is a side view showing an example of a dial outer body according to Modification 3. FIG. FIG. 21 is a cross-sectional view showing an example of an input system according to modification 4. As shown in FIG. FIG. 22 is a cross-sectional view showing an example of an input system according to Modification 4. As shown in FIG. FIG. 23 is a cross-sectional view showing an example of an input system according to Modification 4. As shown in FIG. 24 is a cross-sectional view showing an input system according to Modification 5. FIG.

An embodiment will be described below with reference to the drawings. Each figure shown below is a figure shown typically. Therefore, the size and shape of each part are appropriately exaggerated for easy understanding. In addition, it can be modified as appropriate without departing from the technical concept. In addition, in each figure shown below, the same code|symbol is attached|subjected to the same part and detailed description may be partially abbreviate|omitted. In addition, numerical values such as dimensions and material names of each member described in this specification are examples as an embodiment, and can be appropriately selected and used without being limited thereto. In this specification, terms specifying shapes and geometrical conditions, such as parallel and perpendicular, are to be interpreted to include substantially the same state in addition to strictly meaning.

<First Embodiment>
First, a dial unit 1 and an input system 100 according to the first embodiment will be described.

FIG. 1 is a perspective view showing an input system 100 according to the first embodiment. FIG. 2 is a top view showing the input system 100 according to the first embodiment. FIG. 3a is a partial cross-sectional view showing a portion of the cross section taken along line IIIa--IIIa of FIG. FIG. 3b is a partial cross-sectional view showing a part of the cross section taken along line IIIb--IIIb of FIG. The input system 100 comprises a dial unit 1 and a touch panel 8, as shown in FIGS. 1 to 3b.

The touch panel 8 is capacitive. The touch panel 8 has an input surface 8a and a back surface 8b located on the opposite side of the input surface 8a. The input surface 8a is a surface for detecting a conductive detected portion.

In the example shown in FIG. 1 , the display device 9 is arranged on the rear surface 8 b side of the touch panel 8 . As the display device 9, for example, a display device such as a liquid crystal display, a plasma display, or an organic EL display is used. Alternatively, the display device 9 may display an image by transmitting light through a printed transparent film or the like, or may display an image by light and shade by shielding part of the light with a light shielding material. may The display device 9 displays information, designs, etc. on the input surface 8 a of the touch panel 8 .

A dial unit 1 is a dial unit laminated on a capacitive touch panel 8 . The dial unit 1 includes a support portion 5 fixed on the touch panel 8, a dial outer body 3 rotatably supported by the support portion 5, and rotatable in conjunction with the rotation of the dial outer body 3. an electrode 4 for generating capacitance. In particular, dial unit 1 is provided on input surface 8 a of touch panel 8 . The dial unit 1 inputs rotation information to the touch panel 8 . As shown in FIGS. 3a and 3b, the dial unit 1 includes a support 5, a dial outer body 3, and electrodes 4. As shown in FIGS. The support portion 5 is fixed on the input surface 8a. The dial outer body 3 is rotatably supported by the support portion 5 . Electrode 4 is fixed to dial outer body 3 . Therefore, the electrode 4 can be rotated with respect to the touch panel 8 by rotating the dial outer body 3 with respect to the support portion 5 . Also, the electrodes 4 are detected on the input surface 8 a of the touch panel 8 . By causing the input surface 8 a of the touch panel 8 to detect the rotation of the electrode 4 , rotation information can be input to the touch panel 8 .

A width w7 of the dial unit 1 in the direction d1 perpendicular to the input surface 8a is, for example, 10 mm or more and 30 mm or less. A width w8 of the dial unit 1 in a radial direction d2 perpendicular to the rotation axis O1, which will be described later, is, for example, 54 mm or more and 100 mm or less.

The support 5 is fixed on the input surface 8a as described above. The support portion 5 has an annular shape. A method for fixing the support portion 5 onto the input surface 8a is not particularly limited. The support portion 5 is fixed to the input surface 8a via an adhesive layer (not shown), for example. In this case, a double-sided tape may be used as the adhesive layer. Further, the support portion 5 may be fixed to the input surface 8a via an adhesive layer (not shown). In this case, the support portion 5 may be fixed to the input surface 8a using an adhesive.

The material of the support portion 5 is preferably an insulating material. Since the material of the support portion 5 is an insulating material, it is possible to prevent a conductive member other than the electrode 4 from approaching the input surface 8a and being detected by the input surface 8a. Accuracy in detecting the electrodes 4 can be ensured. The material of the support portion 5 is, for example, resin. More specifically, at least one or more selected from the group consisting of ABS resin, acrylic resin, polycarbonate resin, polypropylene resin, and polyethylene resin may be used as the material of the support portion 5 .

The dial outer body 3 is a member that is pinched and rotated by the user of the dial unit 1 when the user inputs rotation information. The dial outer body 3 is rotatably supported by the support portion 5 as described above. The dial outer body 3 rotates with respect to the support portion 5 around the rotation axis O1 shown in FIGS. 1, 3a and 3b. The rotation axis O1 extends perpendicularly to the input surface 8a.

FIG. 4 is a perspective view showing the dial outer body 3 according to the first embodiment. As shown in FIG. 4 , a through hole 36 is provided in the dial outer body 3 . In the example shown in FIG. 4, the dial outer body 3 has an annular shape. A surface of the dial outer body 3 on the side of the rotation axis O1 is referred to as an inner surface 3 b of the dial outer body 3 . In the example shown in FIG. 4 , the inner surface 3 b of the dial outer body 3 is the surface forming the through hole 36 of the dial outer body 3 . The surface of the dial outer casing 3 opposite to the inner surface 3b is referred to as an outer surface 3c. A surface connecting the inner surface 3b and the outer surface 3c on the side opposite to the input surface 8a of the dial outer casing 3 is referred to as an upper surface 3d of the dial outer casing 3. As shown in FIG. As shown in FIGS. 6A, 6B, and 6C, the inner surface 3b and the outer surface 3c may be in contact with each other on the side opposite to the input surface 8a of the dial outer body 3. FIG. In this case, the position where the inner surface 3b and the outer surface 3c are in contact is regarded as the position of the upper surface 3d of the dial outer body 3. As shown in FIG.

In the example shown in FIGS. 3a and 3b, the dial outer body 3 has a dial outer body main body 31 and a retainer 32. As shown in FIG. The dial outer body main body 31 and the retaining portion 32 have an annular shape.

The dial outer body main body 31 is a portion that is pinched by the user of the dial unit 1 when inputting rotation information. A surface of the dial outer body main body 31 that faces the input surface 8 a is referred to as a bottom surface 31 a of the dial outer body main body 31 . In the example shown in FIGS. 3a and 3b, the bottom surface 31a of the dial outer body main body 31 is provided with grooves 31b. The support portion 5 and the electrode 4 are accommodated inside the groove portion 31b.

The dial outer body 3 covers the electrodes 4 on the touch panel 8 . In particular, the dial jacket 3 covers the electrodes 4 on the input surface 8a. The dial outer body 3 covers the electrodes 4 on the input surface 8a so that the electrodes 4 are not exposed from between the dial outer body 3 and the input surface 8a. This prevents the user from touching the electrode 4 when operating the dial unit 1 . In the example shown in FIGS. 3a and 3b, the electrodes 4 are accommodated in the grooves 31b so that the dial outer body 3 covers the electrodes 4 on the input surface 8a.

In the example shown in Figures 3a and 3b, the dial jacket 3 has an inner surface 3b, an outer surface 3c and an upper surface 3d. The electrode 4 is covered with the inner surface 3b, the outer surface 3c and the upper surface 3d of the dial outer body 3. As shown in FIG. The electrode 4 is surrounded by the inner surface 3b, the outer surface 3c and the upper surface 3d of the dial jacket 3 and the input surface 8a. Thus, the electrodes 4 are covered by the dial outer body 3 so as not to be exposed from between the dial outer body 3 and the input surface 8a.

As will be described later, the dial outer body 3 contains an insulating material. By covering the electrodes 4 on the input surface 8 a , the dial casing 3 insulates the electrodes 4 from the outside of the dial casing 3 on the side covered by the dial casing 3 . In the example shown in Figures 3a and 3b, the dial jacket 3 has an inner surface 3b, an outer surface 3c and an upper surface 3d. In this case, the inner surface 3b, the outer surface 3c and the upper surface 3d may be made of an insulating material. Thereby, the electrode 4 can be insulated from the outside of the dial outer body 3 on the side covered with the dial outer body 3 . As shown in FIGS. 6(a), (b), and (c), which will be described later, the inner surface 3b and the outer surface 3c of the dial outer body 3 may be in contact with each other. In this case, the inner surface 3b and the outer surface 3c may be made of an insulating material. Thereby, the electrode 4 can be insulated from the outside of the dial outer body 3 on the side covered with the dial outer body 3 .

The retaining portion 32 is a portion that prevents the support portion 5 from coming off from the groove portion 31 b of the dial outer body main body 31 . In the example shown in FIG. 3B, the retaining portion 32 also prevents the electrode 4 from coming off from the groove portion 31b. By inserting the retaining portion 32 into the groove portion 31b while the support portion 5 is accommodated in the groove portion 31b, the later-described convex portion 5a of the support portion 5 is removed from the later-described concave portion 3a of the dial outer body main body 31. suppress Further, the retaining portion 32 prevents the later-described parasitic capacitance generating electrode portion 42 of the electrode 4 from coming out of the groove portion 31b by being inserted into the groove portion 31b while the electrode 4 is accommodated in the groove portion 31b. The retaining portion 32 is fixed to the dial outer body main body 31 . As an example, the retaining portion 32 is fixed to the dial outer body main body 31 by being adhered to the dial outer body main body 31 .

The dial outer body 3 contains an insulating material. The material of the dial outer body main body 31 and the retaining portion 32 is preferably an insulating material. As a result, it is possible to prevent conductive members other than the electrodes 4 from approaching the input surface 8a and being detected by the input surface 8a, and to ensure the accuracy with which the input surface 8a of the touch panel 8 detects the electrodes 4. FIG. The material of the dial outer body main body 31 and the retaining portion 32 is resin, for example. More specifically, ABS resin may be used as the material of the dial outer body main body 31 and the retaining portion 32 . As an example, the materials of the dial outer body main body 31 and the retaining portion 32 do not have transparency.

The method by which the support portion 5 supports the dial outer casing 3 is not particularly limited as long as the dial outer casing 3 is rotatable with respect to the support portion 5 . In the example shown in Figures 3a and 3b, the support 5 has a protrusion 5a. The dial outer body 3 has a concave portion 3a. Both the convex portion 5a and the concave portion 3a have an annular shape. In this case, the dial outer body 3 is rotatably supported by the supporting portion 5 by engaging the convex portion 5a and the concave portion 3a. In the example shown in FIGS. 3a and 3b, the protrusion 5a is provided on the outer surface of the support 5. In the example shown in FIGS. The concave portion 3 a is provided on the surface of the dial outer body main body 31 facing the outer surface of the support portion 5 . Although not shown, the support portion 5 may have an annular concave portion, and the dial outer body 3 may have an annular convex portion. In this case, the dial outer body 3 is rotatably supported by the support part 5 by engaging the concave part of the support part 5 with the convex part of the dial outer body 3 .

At least part of the inner surface 3b of the dial outer body 3 according to the first embodiment is inclined so as to reduce the width w1 of the through-hole 36 in the horizontal direction to the input surface 8a as it approaches the input surface 8a. . In the example shown in Figures 3a and 3b, at least a portion of the inner surface 3b of the dial jacket 3 is slanted to reduce the inner shape of the dial jacket 3 as it approaches the input surface 8a. A portion of the inner surface 3b that is inclined so as to reduce the width w1 of the through hole 36 in the direction horizontal to the input surface 8a as it approaches the input surface 8a is referred to as an inner inclined surface 34 . The inner inclined surface 34 is inclined with respect to the input surface 8a. In the example shown in FIGS. 1 to 3b, the inner inclined surface 34 of the dial outer body 3 has a circular cross section parallel to the input surface 8a. The inner inclined surface 34 is inclined so that the width w1 of the through hole 36 (the inner diameter of the dial outer body 3) is reduced as it approaches the input surface 8a. In the example shown in FIGS. 1 to 3b, the inner sloping surface 34 is provided on the dial outer body 31. In the example shown in FIGS.

The electrode 4 is a portion having a portion to be detected on the input surface 8 a of the touch panel 8 . The electrodes 4 are conductive as detected by the input surface 8 a of the capacitive touch panel 8 . As described above, the electrodes 4 are fixed to the dial outer body 3 . A method for fixing the electrode 4 to the dial outer casing 3 is not particularly limited. The electrode 4 may be fixed to the dial outer body main body 31 . The electrode 4 may be fixed to the dial outer body 3 by being sandwiched between the dial outer body main body 31 and the retaining portion 32 . The electrode 4 moves in conjunction with the movement of the dial outer body 3 . For example, when the dial outer body 3 rotates with respect to the support portion 5 , the electrode 4 also rotates with respect to the support portion 5 . Further, when the touch panel 8 has a force sensor as will be described later, when the dial outer body 3 is pushed toward the input surface 8a, the electrodes 4 are also pushed toward the input surface 8a.

The electrode 4 has a detection electrode portion 41 , a parasitic capacitance generating electrode portion 42 and a connecting portion 43 . The detection electrode portion 41 is located closer to the input surface 8a than the parasitic capacitance generating electrode portion 42 and the connecting portion 43 are. The parasitic capacitance generating electrode portion 42 is separated from the input surface 8 a and the detection electrode portion 41 . The connecting portion 43 connects the detection electrode portion 41 and the parasitic capacitance generating electrode portion 42 . In the example shown in FIGS. 3 a and 3 b , the electrode 4 has a first connection 431 and a second connection 432 as the connection 43 . Further, the electrode 4 has a first detection electrode portion 411 and a second detection electrode portion 412 as the detection electrode portion 41 .

FIG. 5 is a perspective view showing the electrode 4 according to the first embodiment. In the example shown in FIG. 5, the parasitic capacitance generating electrode portion 42 has an annular shape. The first connecting portion 431 and the second connecting portion 432 extend from the parasitic capacitance generating electrode portion 42 toward the input surface 8a. The first connecting portion 431 and the second connecting portion 432 face each other with the center of the annular parasitic capacitance generating electrode portion 42 interposed therebetween. The first connecting portion 431 connects the parasitic capacitance generating electrode portion 42 and the first detecting electrode portion 411 . The second connecting portion 432 connects the parasitic capacitance generating electrode portion 42 and the second detecting electrode portion 412 . The first detection electrode portion 411 and the second detection electrode portion 412 are detected on the input surface 8a.

The material of the electrode 4 is metal such as copper, for example. The electrode 4 may be formed by connecting a plurality of members, or may be formed from an integral member. When forming the electrode 4 from an integral member, the electrode 4 may be formed by bending an integral (single) metal plate.

The electrode 4 having the detection electrode portion 41, the parasitic capacitance generating electrode portion 42, and the connecting portion 43 shown in FIG. 5 is formed of an integral metal plate. In particular, the electrode 4 is formed by bending an integral metal plate. As described above, the electrode 4 includes the detection electrode portion 41 detected on the input surface 8a, the parasitic capacitance generating electrode portion 42 separated from the input surface 8a and the detection electrode portion 41, and the detection electrode portion 41 and the parasitic capacitance. and a connection portion 43 that connects with the generation electrode portion 42 . The metal plate forming the electrode 4 is bent at the boundary between the detection electrode portion 41 and the connecting portion 43 and the boundary between the parasitic capacitance generating electrode portion 42 and the connecting portion 43 . In other words, by bending the metal plate, a boundary between the detection electrode portion 41 and the connecting portion 43 and a boundary between the parasitic capacitance generating electrode portion 42 and the connecting portion 43 are formed. In the example shown in FIG. 5, the metal plate forming the electrode 4 is bent at right angles at the boundary between the detection electrode portion 41 and the connecting portion 43 and at the boundary between the parasitic capacitance generating electrode portion 42 and the connecting portion 43 .

In the example shown in FIG. 3a, at least part of the inner surface 3b of the dial outer body 3 is inclined so as to reduce the width w1 of the through hole 36 in the horizontal direction to the input surface 8a as it approaches the input surface 8a. That is, the dial outer body 3 has an inner inclined surface 34 . In the radial direction d2 perpendicular to the rotation axis O1 along which the dial outer casing 3 rotates with respect to the support portion 5, the detection electrode portion 41 is positioned on the rotation axis O1 side of the connecting portion 43. As shown in FIG. In addition, the parasitic capacitance generating electrode portion 42 is located on the side opposite to the rotation axis O1 side of the connecting portion 43 in the radial direction d2.

In the example shown in FIG. 3a, the detection electrode portion 41 is located on the rotational axis O1 side of the connecting portion 43 in the radial direction d2, and the parasitic capacitance generating electrode portion 42 is located on the rotational axis O1 side of the connecting portion 43 in the radial direction d2. Located opposite. According to this feature, when the dial outer body 3 has the inner inclined surface 34, as shown in FIG. The detection electrode part 41 can be arranged so as to partially overlap. Therefore, the area on the input surface 8a side when viewed from the inner inclined surface 34 of the dial outer casing 3 can be utilized as an area in which the detection electrode portion 41 is arranged. Further, the parasitic capacitance generating electrode portion 42 can be arranged at a position farther from the inner inclined surface 34 than when the parasitic capacitance generating electrode portion 42 is positioned on the rotation axis O1 side of the connecting portion 43 in the radial direction d2. Therefore, it is possible to secure a larger space for housing the parasitic capacitance generating electrode portion 42 inside the dial outer body 3 having the inner inclined surface 34 . In particular, the parasitic capacitance generating electrode section 42 having a larger volume can be arranged at a position separated from the input surface 8a and the sensing electrode section 41 by a larger distance. As a result, the electrode 4 having the parasitic capacitance generating electrode portion 42 is formed while sufficiently increasing the distance separating the parasitic capacitance generating electrode portion 42 from the input surface 8a and the detection electrode portion 41 and the volume of the parasitic capacitance generating electrode portion 42. It can be covered by a dial jacket 3 . As described above, when the dial outer casing 3 has the inner inclined surface 34 , the electrode 4 can be covered with the dial outer casing 3 while downsizing the dial outer casing 3 .

The position of the detection electrode portion 41 is determined so as to be detected by the input surface 8 a of the touch panel 8 . The position of the detection electrode portion 41 is not particularly limited as long as it is detected by the input surface 8a. The sensing electrode portion 41 may be spaced apart from the input surface 8a. In other words, an air layer may be positioned between the detection electrode portion 41 and the input surface 8a, or a member other than the electrode 4 and the touch panel 8 may be positioned between the detection electrode portion 41 and the input surface 8a. You may have The sensing electrode portion 41 may be in contact with the input surface 8a. The parasitic capacitance generating electrode portion 42 generates parasitic capacitance by being insulated from the outside by the dial outer body 3 . The connecting portion 43 connects the detection electrode portion 41 and the parasitic capacitance generating electrode portion 42 . Due to this configuration, the capacitance of the electrode 4 detected by the input surface 8 a of the touch panel 8 is increased by the parasitic capacitance of the parasitic capacitance generating electrode section 42 . Thereby, the detection electrode portion 41 is detected on the input surface 8a of the touch panel 8 with high accuracy.

From the viewpoint of further improving the accuracy with which the sensing electrode portion 41 is sensed by the input surface 8a, it is preferable that the volume of the parasitic capacitance generating electrode portion 42 is large. Moreover, it is preferable that the parasitic capacitance generating electrode portion 42 is separated from the input surface 8a and the detection electrode portion 41 by a larger distance.

Note that the shape of the electrode 4 is not limited to the above example. The shape of the electrode 4 is particularly limited as long as the parasitic capacitance generating electrode portion 42 generates a parasitic capacitance of sufficient magnitude and the detection electrode portion 41 is detected on the input surface 8a such that the rotation of the electrode 4 is detected. can't

According to the dial unit 1 including the support portion 5, the dial outer body 3, and the electrodes 4 described above, the dial outer body 3 and the electrodes are rotated by the user pinching the dial outer body 3 and rotating it with respect to the support portion 5. 4 rotates together. The dial outer body 3 and the electrode 4 are also collectively referred to as a dial part 2 . Rotation information can be input to the touch panel 8 by rotating the dial part 2 with respect to the touch panel 8 and detecting the position of the detection electrode portion 41 of the rotating electrode 4 by the input surface 8 a of the touch panel 8 . The rotation information is, for example, the amount and speed of rotation of the dial outer body 3 by the user.

Here, in the dial unit 1 according to the first embodiment, at least part of the input surface 8a is visible through the through hole 36 of the dial outer body 3. As shown in FIG. Therefore, a portion of the input surface 8a that is visible through the through hole 36 can be used as an area for displaying information, designs, and the like to be shown to the user. A visible area through the through hole 36 of the input surface 8a is referred to as a visible area 8c. For example, when the display device 9 is arranged on the rear surface 8b side of the touch panel 8 as shown in FIG. In the examples shown in FIGS. 1 and 2, the letter A is displayed in the visible area 8c. The information displayed in the visible area 8c is information prompting the user to operate the dial unit 1, for example. The information displayed in the visual recognition area 8c may be information indicating the result of inputting rotation information through the dial unit 1. FIG.

According to the dial unit 1 and the input system 100 according to the first embodiment, the visual recognition area 8c can be used as an area for displaying information, designs, and the like, so that the degree of freedom in designing the input surface 8a is improved. Therefore, the overall design of the input system 100 can be ensured while the dial unit 1 is provided on the input surface 8a.

Here, the action of the inner inclined surface 34 will be described. The user does not necessarily see the visual recognition area 8c from the front, and it is also conceivable that the user looks at the visual recognition area 8c from an oblique direction. Depending on the application of the input system 100, it is also assumed that the user often looks at the visual recognition area 8c from an oblique direction. For example, when the dial unit 1 is provided on the touch panel 8 included in the navigation device of an automobile to form an input system 100, a user such as a driver looks at the visual recognition area 8c while maintaining the line of sight at a position where the front of the automobile can be confirmed. is also assumed. In this case, it is considered that a user such as a driver often sees the visual recognition area 8c from an oblique direction. Since the dial outer body 3 has the inner inclined surface 34, it is possible to prevent the user's line of sight from being blocked by the dial outer body 3 when the user views the visual recognition area 8c from an oblique direction.

6A and 6B are diagrams showing dial units 1 having various dial outer bodies 3 with different forms of inner inclined surfaces 34. FIG. FIG. 6 shows nine dial units 1 (a) to (i). FIG. 6 shows only the cross-sectional outline of the dial unit 1 . Boundaries between members forming the dial unit 1 are omitted from FIG. In the drawings other than FIG. 6(a), reference numerals are omitted except for the visual recognition area 8c, the first area 8d, the second area 8e, the distance w2, and the distance w3, which will be described later.

The shape of the inner inclined surface 34 is appropriately determined according to the use of the dial unit 1 and the like. The form of the inner inclined surface 34 can be changed by changing the distance w2 and the distance w3 shown in FIG. The distance w2 is the distance between the inner inclined surface 34 and the input surface 8a in the direction d1 of the normal to the input surface 8a. A distance w3 is a distance between the outer surface 3c of the dial outer body 3 and the inner inclined surface 34 in the radial direction d2 perpendicular to the rotation axis O1. In FIG. 6, the dial outer bodies 3 having different forms of the inner inclined surfaces 34 are arranged so that the distance w2 decreases from top to bottom in FIG. 6 and the distance w3 decreases from left to right in the drawing. It is 6A, 6D, and 6G, the distance w2 is zero because the entire inner surface 3b is the inner inclined surface . In FIGS. 6A, 6B, and 6C, the distance w3 is 0 because the inner inclined surface 34 is in contact with the outer surface 3c.

The greater the inclination of the inner inclined surface 34, the more obliquely the visible area 8c can be seen. Also, the larger the inclination of the inner inclined surface 34, the wider the range of the visual recognition area 8c that can be seen from a specific position in the oblique direction. On the other hand, increasing the inclination of the inner inclined surface 34 reduces the volume of the dial outer body 3 . When the volume of the dial outer body 3 becomes small, it becomes difficult to increase the volume of the electrode 4 accommodated inside the dial outer body 3 . In particular, it becomes difficult to increase the volume of the parasitic-capacitance-generating electrode portion 42, and it becomes difficult for the parasitic-capacitance-generating electrode portion 42 to generate a large parasitic capacitance. The form of the inner inclined surface 34 may be determined in consideration of such circumstances.

Here, regarding the display device 9 arranged on the back surface 8b side of the touch panel 8, the brightness when the display device 9 is viewed from an oblique direction may be lower than the brightness when the display device 9 is viewed from the front. . In particular, the luminance of the display device 9 may decrease as the display device 9 is viewed from a more oblique direction. In this case, the greater the angle formed by the line of sight viewing the input surface 8a with respect to the direction d1 of the normal to the input surface 8a, the lower the luminance when viewing the input surface 8a. The form of the inner inclined surface 34 may be determined in consideration of such circumstances.

As an example, the shape of the inner inclined surface 34 may be determined as follows. A dashed line L1 shown in FIG. 3a indicates a line of sight at which the luminance of the input surface 8a is half the luminance when viewed from the direction d1 perpendicular to the input surface 8a. The angle formed between the direction in which the luminance of the input surface 8a is half the value when viewed from the direction d1 of the normal to the input surface 8a (the direction in which the line of sight L1 extends) and the normal L2 to the input surface 8a is defined as the half width angle θ1. A first region 8d is defined as a region on the input surface 8a that is visible through the through hole 36 from an arbitrary direction that forms an angle with the normal L2 of the input surface 8a that is equal to or less than the half width angle θ1. In this case, the shape of the inner inclined surface 34 may be determined such that the first region 8d is wider. By widening the first area 8d, it is possible to widen the area of the input surface 8a that can be visually recognized through the through hole 36 from the line of sight forming the half width angle θ1 with the normal L2 of the input surface 8a.

An example of a method of determining the shape of the inner inclined surface 34 so that the first region 8d is wider will be described. The distance w3 is the same between the dial casing 3 shown in FIG. 6(a) and the dial casing 3 shown in FIG. 6(d). On the other hand, the magnitude of the distance w2 is smaller in (d) than in (a). For this reason, the inner inclined surface 34 is inclined with respect to the normal direction d1 of the input surface 8a by an angle larger than the half-value width angle θ1 in (a), whereas it is inclined by the half-value width angle θ1 in (d). Inclined. The first region 8d is wider in (d) than in (a) because the inner inclined surface 34 has such a shape. In this case, it is preferable to select the form shown in (d) rather than the form shown in (a) as the form of the inner inclined surface 34 from the viewpoint of widening the first region 8d.

Another example of the method of determining the shape of the inner inclined surface 34 so that the first region 8d is wider will be described. The distance w2 is the same between the dial casing 3 shown in FIG. 6(g) and the dial casing 3 shown in FIG. 6(h). On the other hand, the magnitude of the distance w3 is smaller in (h) than in (g). For this reason, the inner inclined surface 34 is inclined by an angle larger than the half-value width angle θ1 with respect to the normal direction d1 of the input surface 8a in (g), whereas it is inclined by the half-value width angle θ1 in (h). Inclined. With the inner inclined surface 34 having such a shape, the first region 8d is wider in (h) than in (g). In this case, it is preferable to select the form shown in (h) rather than the form shown in (g) as the form of the inner inclined surface 34 from the viewpoint of widening the first region 8d.

A region on the input surface 8a that is visible through the through hole 36 from a direction perpendicular to the input surface 8a is defined as a second region 8e. In the example shown in FIG. 3a, the second area 8e corresponds to the viewing area 8c described above. In this case, the shape of the inner inclined surface 34 may be determined such that the area of the first region 8d is 80% or more of the area of the second region 8e. That is, the area of the region on the input surface 8a that is visible through the through hole 36 from any direction in which the angle formed with the normal L2 of the input surface 8a is equal to or less than the half width angle θ1 is It may be 80% or more of the area of the region on the input surface 8a that is visible through the through-hole 36 . By setting the area of the first region 8d to 80% or more of the area of the second region 8e, the input surface can be displayed with a luminance that is at least half the luminance when viewed from the direction d1 perpendicular to the first region 8d, that is, the input surface 8a. The area of the input surface 8a that can be visually recognized through the through hole 36 from any line of sight where the 8a is visually recognized can be made sufficiently wider than the second area 8e.

Note that the area of the first region 8d may be adjusted by a method other than selecting a preferable form of the inner inclined surface 34 . For example, the area of the first region 8 d may be adjusted by adjusting the dimensions of the portion of the dial outer body 3 other than the inner inclined surface 34 .

In addition, the inventors of the present invention found that in a general device such as a commercially available smartphone in which the display device 9 is arranged on the back surface 8b side of the touch panel 8, the half width angle θ1 is about 27°. rice field. Based on this finding, the shape of the inner inclined surface 34 may be defined as follows. The area of the region on the input surface 8a that is visible through the through-hole 36 from any direction with an angle of 27° or less with respect to the normal L2 of the input surface 8a (also referred to as the 27° visible region) The shape of the inner inclined surface 34 may be determined so as to occupy 80% or more of the area of the region 8e. That is, the area of the region on the input surface 8a that is visible through the through-hole 36 from any direction that forms an angle of 27° or less with respect to the normal L2 of the input surface 8a is the area of the through-hole from the direction perpendicular to the input surface 8a. It may be 80% or more of the area of the area on the input surface 8a that is visible through . As a result, the first region 8d can be sufficiently widened in a general device having a half width angle θ1 of about 27°. Note that the area of the 27° visual recognition area may be adjusted by a method other than selecting a preferable form of the inner inclined surface 34 .

The shape of the inner inclined surface 34 may be determined from a viewpoint other than the viewpoint of adjusting the areas of the first region 8d and the 27° visual recognition region described above. As an example, consider a case where it is assumed that the visual recognition area 8c is viewed from a line of sight whose angle with respect to the normal L2 of the input surface 8a is equal to or greater than the half width angle θ1 or equal to or greater than 27°. In this case, the shape of the inner inclined surface 34 may be determined so that the visible region 8c can be visually recognized from an assumed line of sight.

Various treatments can be appropriately applied to the surface of the dial outer body 3 from the viewpoint of displaying information and designs and improving the operability of the dial unit 1 . Specifically, the surface of the dial unit 1 may be treated to prevent the user's fingers from slipping when pinching the dial outer body 3 . Moreover, the surface of the dial unit 1 may be processed to reduce the reflectance of light from the outside of the input system 100 .

An example of the treatment applied to the surface of the dial outer body 3 is surface processing. Information, design, etc. can be displayed on the surface of the dial outer body 3 by subjecting the dial outer body 3 to surface processing. Further, by subjecting the dial outer body 3 to a surface treatment, the surface of the dial outer body 3 can be roughened so that the user's fingers do not slip easily when the user pinches the dial outer body 3 . As described above, when the material of the dial outer casing 3 is resin, surface processing is easier than when the material is metal or the like.

Different treatments may be applied to the surface of the dial outer body 3 for each portion. For example, the outer surface 3c, the inner inclined surface 34 and the upper surface 3d of the dial jacket 3 shown in FIG. 3a may be treated differently. An example of the dial outer body 3 in which different processing is performed for each portion will be described. When the user picks up the dial jacket 3 shown in FIG. 3a, it is assumed that the user's fingers touch the outer surface 3c. Further, since the outer surface 3c is perpendicular to the input surface 8a, it is difficult for the user to visually recognize it. For this reason, the outer surface 3c can be treated with emphasis on making it difficult for the user's fingers to slip when pinching the dial outer body 3, rather than reducing the design and reflectance. On the other hand, since the inner inclined surface 34 and the upper surface 3d are not perpendicular to the input surface 8a, they are more visible to the user than the outer surface 3c. Therefore, the inner inclined surface 34 and the upper surface 3d can be treated with emphasis on design and reduction of reflectance.

Specifically, the outer surface 3c is processed so that the user's fingers do not easily slip when pinching the dial outer body 3, and the inner inclined surface 34 and the upper surface 3d are designed. It is possible to give priority to surface treatment. In this case, the surface roughness of the outer surface 3c may be larger than the surface roughness of the inner inclined surface 34 and the upper surface 3d.

The color of the dial outer body 3 is black, for example. When the color of the dial casing 3 is black, from the viewpoint of ensuring the insulation of the dial casing 3, the dial casing 3 should be colored black using a material that ensures the insulation of the dial casing 3. is preferred. For example, in order to give the dial outer body 3 a black color, it is preferable not to use conductive carbon black.

Although not shown, the dial unit 1 may further include a structure that prevents liquid such as water from entering between the dial outer body 3 and the support portion 5 and between the electrode 4 and the support portion 5. good.

In the input system 100, the dial unit 1 can be partially or entirely removed from the touch panel 8 and replaced. For example, by removing the support portion 5 of the dial unit 1 from the input surface 8a, the entire dial unit 1 can be removed from the touch panel 8 and replaced. As an example of a method of removing part of the dial unit 1 from the touch panel 8 and replacing it, there is a method of removing the dial outer body 3 and the part fixed to the dial outer body 3 from the touch panel 8 and replacing it. In the input system 100 shown in FIG. 3 a, the electrodes 4 are fixed to the dial jacket 3 . In the input system 100 shown in FIG. 3a, the dial armor 3 and the electrodes 4 are removed from the touch panel 8 by removing the dial armor 3 from the support 5 while the support 5 is still fixed to the input surface 8a. can be exchanged.

<Second Embodiment>
Next, a dial unit 1 and an input system 100 according to a second embodiment will be described. In addition, in the dial unit 1 and the input system 100 according to the second embodiment, the parts that can be configured in the same manner as the dial unit 1 and the input system 100 according to the first embodiment described above are the same as those in the first embodiment. The same reference numerals as those used for the corresponding parts in the form of 1 are used, and overlapping descriptions are omitted.

In the first embodiment, the dial unit 1 in which the dial outer body 3 has the inner inclined surface 34 and the outer surface 3c of the dial outer body 3 is not provided with a surface inclined with respect to the input surface 8a. explained. However, the shape of the dial outer body 3 is not limited to this. The dial outer body 3 is inclined so that the width w4 of the dial outer body 3 in the direction horizontal to the input surface 8a increases as at least a part of the outer surface 3c of the dial outer body 3 approaches the input surface 8a, and Alternatively, at least a portion of the inner surface 3b of the dial outer body 3 may be inclined so that the width w1 of the through-hole 36 in the horizontal direction to the input surface 8a decreases as it approaches the input surface 8a. In other words, at least a part of the outer surface 3c of the dial outer body 3 is inclined so as to increase the outer diameter w4 of the dial outer body 3, which will be described later, as it moves away from the position of the upper surface 3d, and/or At least a portion of the inner surface 3b of the body 3 may be inclined so that the inner diameter w1 of the dial outer body 3 is reduced as it moves away from the position of the upper surface 3d. In other words, the dial outer body 3 may have at least one of the inner inclined surface 34 and the outer inclined surface 35 to be described later.

FIG. 7a is a cross-sectional view showing an example of the input system 100 according to the second embodiment. According to the input system 100 according to the second embodiment, as in the input system 100 according to the first embodiment, the user pinches the dial outer body 3 of the dial unit 1 and presses against the support portion 5 . Rotation causes the electrodes 4 to rotate with respect to the touch panel 8 . By causing the input surface 8 a of the touch panel 8 to detect the rotation of the electrode 4 , rotation information can be input to the touch panel 8 . According to the dial unit 1 according to the second embodiment, at least part of the input surface 8a is visible through the through hole 36 of the dial outer body 3, as in the dial unit 1 according to the first embodiment. be.

As shown in FIG. 7a, at least part of the outer surface 3c of the dial outer body 3 of the dial unit 1 according to the second embodiment is inclined toward the input surface 8a in a direction parallel to the input surface 8a. is inclined so as to expand the width w4 of . In the example shown in FIG. 7a, at least a portion of the outer surface 3c of the dial jacket 3 is slanted so as to enlarge the contour of the dial jacket 3 as it approaches the input surface 8a. A portion of the outer surface 3c that is inclined so as to increase the width w4 of the dial outer body 3 in the horizontal direction to the input surface 8a as it approaches the input surface 8a is referred to as an outer inclined surface 35 . The outer inclined surface 35 is inclined with respect to the input surface 8a. The outer inclined surface 35 of the dial outer body 3 according to the second embodiment has a circular cross section parallel to the input surface 8a. The outer inclined surface 35 is inclined so as to increase the width (outer diameter of the dial outer body 3) w4 of the dial outer body 3 as it approaches the input surface 8a. In the example shown in FIG. 7a, a portion of the outer surface 3c of the dial outer body 3 is an outer inclined surface 35. In the example shown in FIG. In the example shown in FIG. 7a, the dial jacket 3 does not have an inner inclined surface 34. In the example shown in FIG.

The action of the outer inclined surface 35 will be described. Since the dial outer body 3 has the outer inclined surface 35, the area of the outer surface 3c is increased. As a result, when the user pinches the outer surface 3c of the dial housing 3 and rotates the dial housing 3, the user can easily pinch the dial housing 3.例文帳に追加In particular, even when the width w5 of the dial outer body 3 in the direction d1 perpendicular to the input surface 8a is designed to be small, the user can easily pick up the dial outer body 3. By designing the width w5 to be small, it is possible to prevent the user's line of sight from being blocked by the dial outer body 3 when the user views the visual recognition area 8c from an oblique direction. As described above, the width w5 can be designed to be small by the outer inclined surface 35 while ensuring the ease of gripping the dial housing 3, thereby suppressing the dial housing 3 from obstructing the line of sight viewing the visual recognition area 8c from an oblique direction. . Furthermore, by designing the width w5 small, the above-mentioned first area 8d shown in FIG. 7a and the 27° viewing area can be widened.

The width w5 may be determined such that the area of the first region 8d is 80% or more of the area of the second region 8e. When the dial outer body 3 does not have the inner inclined surface 34 and the through hole 36 has a cylindrical shape as shown in FIG. If the relationship of the following formula (1) is established between θ1 and , the area of the first region 8d is 80% or more of the area of the second region 8e.

The width w5 may be determined such that the area of the above-described 27° visual recognition area is 80% or more of the area of the above-described second area 8e. In the case of the dial outer body 3 shown in FIG. 7a, if the relationship of the following formula (2) is established between the width w5 and the radius w6 of the through hole 36, the area of the 27° visible region is the area of the second region 8e 80% or more of

The electrode 4 of the dial unit 1 shown in FIG. 7a is formed by bending a metal plate like the electrode 4 shown in FIG. In the example shown in FIG. 7a, at least a part of the outer surface 3c of the dial outer body 3 is inclined so as to increase the width w4 of the dial outer body 3 in the direction horizontal to the input surface 8a as it approaches the input surface 8a. ing. That is, the dial outer body 3 has an outer inclined surface 35 . In the radial direction d2 perpendicular to the rotation axis O1 in which the dial outer body 3 rotates with respect to the support portion 5, the detection electrode portion 41 is located on the opposite side of the connection portion 43 from the rotation axis O1 side. Further, the parasitic capacitance generating electrode portion 42 is located on the rotation axis O1 side of the connecting portion 43 in the radial direction d2.

In the example shown in FIG. 7a, the detection electrode portion 41 is located on the opposite side of the rotation axis O1 side of the connecting portion 43 in the radial direction d2, and the parasitic capacitance generating electrode portion 42 is located on the rotation axis line of the connecting portion 43 in the radial direction d2. Located on the O1 side. According to this feature, when the dial outer body 3 has the outer sloped surface 35, at least a part of the detection electrode part 41 is at least the outer sloped surface 35 in the direction d1 perpendicular to the input surface 8a, as shown in FIG. 7a. The detection electrode part 41 can be arranged so as to partially overlap. Therefore, the area on the input surface 8a side when viewed from the outer inclined surface 35 of the dial outer body 3 can be utilized as an area in which the detection electrode portion 41 is arranged. In addition, compared to the case where the parasitic capacitance generating electrode portion 42 is located on the side opposite to the rotation axis O1 side of the connecting portion 43 in the radial direction d2, the parasitic capacitance generating electrode portion 42 is positioned further away from the outer inclined surface 35. can be placed in Therefore, it is possible to secure a larger space for housing the parasitic capacitance generating electrode portion 42 inside the dial outer body 3 having the outer inclined surface 35 . In particular, the parasitic capacitance generating electrode section 42 having a larger volume can be arranged at a position separated from the input surface 8a and the sensing electrode section 41 by a larger distance. As a result, the electrode 4 having the parasitic capacitance generating electrode portion 42 is formed while sufficiently increasing the distance separating the parasitic capacitance generating electrode portion 42 from the input surface 8a and the detection electrode portion 41 and the volume of the parasitic capacitance generating electrode portion 42. It can be covered by a dial jacket 3 . As described above, when the dial outer casing 3 has the outer inclined surface 35 , the electrode 4 can be covered with the dial outer casing 3 while miniaturizing the dial outer casing 3 .

In the example shown in FIG. 7a, the inner surface 3b of the dial outer body 3 does not have a portion inclined so as to reduce the width w1 of the through-hole 36 in the horizontal direction to the input surface 8a as it approaches the input surface 8a. That is, in the example shown in FIG. 7a, the dial jacket 3 has an outer slanted surface 35 and does not have an inner slanted surface 34 . However, the shape of the dial outer body 3 having the outer inclined surface 35 is not limited to this. FIG. 7b is a cross-sectional view showing an example of the input system 100 according to the second embodiment. In the example shown in FIG. 7b, the dial sheath 3 is arranged so that the width w4 of the dial sheath 3 in the direction horizontal to the input surface 8a increases as at least part of the outer surface 3c of the dial sheath 3 approaches the input surface 8a. and at least a part of the inner surface 3b of the dial outer body 3 is inclined so that the width w1 of the through-hole 36 in the horizontal direction to the input surface 8a decreases as it approaches the input surface 8a. That is, in the example shown in FIG. 7b, the dial outer body 3 has an inner inclined surface 34 and an outer inclined surface 35. As shown in FIG.

Even in the dial unit 1 in which the dial outer body 3 has the inner inclined surface 34 and the outer inclined surface 35, the above-described effects of the inner inclined surface 34 and the outer inclined surface 35 can be obtained.

<Third Embodiment>
Next, a dial unit 1 and an input system 100 according to a third embodiment will be described. In the dial unit 1 and the input system 100 according to the third embodiment, the parts that can be configured in the same manner as the dial unit 1 and the input system 100 according to the first and second embodiments described above are The same reference numerals as those used for the corresponding portions in the first and second embodiments are used, and overlapping explanations are omitted.

FIG. 8 is a cross-sectional view showing an example of the input system 100 according to the third embodiment. According to the input system 100 according to the third embodiment, as in the input system 100 according to the first and second embodiments, the user pinches the dial outer body 3 of the dial unit 1 to open the support portion 5 . By rotating with respect to , the electrode 4 is rotated with respect to the touch panel 8 . By causing the input surface 8 a of the touch panel 8 to detect the rotation of the electrode 4 , rotation information can be input to the touch panel 8 . According to the dial unit 1 according to the third embodiment, at least a part of the input surface 8a passes through the through hole 36 of the dial outer body 3, similarly to the dial units 1 according to the first and second embodiments. Visible.

As shown in FIG. 8, the dial unit 1 according to the third embodiment further includes a transparent portion 6. As shown in FIG. At least part of the transparent portion 6 is arranged inside the through hole 36 . In the example shown in FIG. 8 , the transparent portion 6 is fixed to the dial outer body 3 . As a result, the transparent portion 6 rotates with respect to the support portion 5 together with the dial outer body 3 and the electrode 4 . In the example shown in FIG. 8, the surface of the transparent portion 6 opposite to the input surface 8a is flat.

As used herein, the terms "transparent" and "transmittance" mean, for example, a visible light transmittance of 50% or more. "Transparent" or "transmissive" may mean that the visible light transmittance is 80% or more.

The action of the transparent portion 6 will be described. In the example shown in FIG. 8, the light emitted from the input surface 8a passes through the transparent portion 6 and reaches the eyes of the user. Here, since the speed of light is slower in the transparent portion 6 than in the air, the light emitted from the input surface 8a and passed through the transparent portion 6 travels between the transparent portion 6 and the atmosphere as indicated by the dashed-dotted line L3 shown in FIG. is refracted at the interface with Therefore, compared to the case where the dial unit 1 does not include the transparent portion 6, the visual recognition area 8c can be seen even from an oblique direction. Moreover, the range of the visual recognition area 8c that can be seen from a specific position in the oblique direction is widened. Furthermore, by refracting light at the interface between the transparent portion 6 and the atmosphere, the first region 8d and the 27° visible region can be widened.

The refractive index of the transparent portion 6 is preferably greater than 1.4 and less than 1.6. As an example, the transparent portion 6 includes a material with a refractive index greater than 1.4 and less than 1.6. As an example, the transparent portion 6 is made of a material having a refractive index greater than 1.4 and less than 1.6. As an example, the transparent portion 6 contains a resin material. The resin material contained in the transparent portion 6 and serving as the material of the transparent portion 6 is, for example, at least one resin selected from the group consisting of acrylic resin, polycarbonate resin, polypropylene resin, polyethylene resin and ABS resin. When the transparent portion 6 contains a resin material, by setting the refractive index of the transparent portion 6 to be greater than 1.4, low-refractive fine particles such as hollow silica are used to prepare the resin material that will be the material of the transparent portion 6. no longer need to be mixed with Therefore, it is possible to prevent an increase in cost and an increase in the haze of the transparent portion 6 due to the formation of the transparent portion 6 by mixing low-refractive fine particles. By setting the refractive index of the transparent portion 6 to be less than 1.6, there is no need to prepare an expensive resin material for the transparent portion 6 . The material of the transparent portion 6 may be glass.

Also, the touch panel 8 may have a force sensor. In this case, information can also be input to the touch panel 8 by pressing the dial unit 1 toward the input surface 8a. In this case, if the transparent portion 6 is provided inside the through hole 36, the surface of the dial unit 1 touched by the user when pushing the dial unit 1 increases, so the operation of pushing the dial unit 1 becomes easier. becomes.

Although FIG. 8 shows an example in which the surface of the transparent portion 6 is flat, the shape of the surface of the transparent portion 6 may be selected from the viewpoint of making the visible region 8c easily visible from an oblique direction. . FIG. 9 is a cross-sectional view showing another example of the input system 100 according to the third embodiment. In the example shown in FIG. 9, the surface of the transparent portion 6 opposite to the input surface 8a has a convex lens shape. According to the transparent portion 6 shown in FIG. 9, the light emitted from the input surface 8a and passed through the transparent portion 6 is refracted on the convex lens surface. Therefore, compared to the case where the dial unit 1 includes the transparent portion 6 shown in FIG. 8, the visual recognition area 8c can be seen even from an oblique direction. Moreover, the range of the visual recognition area 8c that can be seen from a specific position in the oblique direction is widened. Furthermore, the first area 8d and the 27° viewing area can be made wider.

Although not shown, the surface of the transparent portion 6 opposite to the input surface 8a may be processed so as to have a large surface roughness. In this case, the light emitted from the input surface 8a and passed through the transparent portion 6 is scattered by the surface having a large surface roughness. Therefore, even when the user views the visual recognition area 8c from an oblique direction, the scattered light can reach the user's eyes.

8 and 9 show examples in which the transparent portion 6 is fixed to the dial outer casing 3, but the transparent portion 6 does not have to be fixed to the dial outer casing 3. FIG. FIG. 10a is a cross-sectional view showing another example of the input system 100 according to the third embodiment. In the example shown in FIG. 10a, the transparent portion 6 is not fixed to the dial jacket 3. In the example shown in FIG. In the example shown in FIG. 10a, the transparent portion 6 is spaced apart from the dial jacket 3. In the example shown in FIG. The dial outer body 3 is relatively movable with respect to the transparent portion 6 . By allowing the dial outer body 3 to move relative to the transparent portion 6, for example, the dial outer body 3 can be made rotatable with respect to the input surface 8a while the transparent portion 6 is fixed on the input surface 8a. Since the transparent part 6 is fixed on the input surface 8a, the shape of the transparent part 6 can be designed on the assumption that the transparent part 6 does not rotate with respect to the input surface 8a. For example, when the input surface 8a is installed perpendicular to the horizontal plane, the input surface 8a is easily visible from a viewpoint shifted upward with respect to the front of the input surface 8a, but from a viewpoint shifted to the left or right. The shape of the transparent portion 6 can be designed so that the input surface 8a is difficult to see.

The transparent portion 6 may be used as the support portion 5 when the transparent portion 6 is fixed on the input surface 8a as shown in FIG. 10a. In this case, although not shown, the inner surface 3b of the dial outer body 3 may be provided with an annular concave portion, and the transparent portion 6 may be provided with an annular convex portion 5a that engages with the annular concave portion. Although not shown, the inner surface 3b of the dial outer body 3 may be provided with an annular projection, and the transparent portion 6 may be provided with an annular recess that meshes with the annular projection.

Further, the dial unit 1 may further include a mirror 61 arranged on the inner surface 3b side of the dial outer body 3, as shown in FIG. 10b. In the example shown in FIG. 10b, the dial unit 1 comprises a transparent portion 6 fixed to the dial jacket 3 and further comprises a mirror 61. In the example shown in FIG. In the example shown in FIG. 10b, the mirror 61 is arranged between the inner surface 3b of the dial jacket 3 and the surface of the transparent portion 6. In the example shown in FIG. In particular, the mirror 61 is arranged between the surface of the transparent portion 6 and the portion of the inner surface 3 b of the dial outer body 3 where the inner inclined surface 34 is not provided. In the example shown in FIG. 10b, the mirror 61 is fixed to the dial jacket 3 and fixed to the transparent part 6. In the example shown in FIG. The mirror 61 has a cylindrical shape extending in the direction d1 perpendicular to the input surface 8a. Also, the mirror 61 has a mirror surface 61a that reflects light. A mirror surface 61 a of the mirror 61 faces the side opposite to the inner surface 3 b of the dial outer casing 3 . The mirror surface 61a that reflects light has a higher light reflectance than the surface of the dial outer casing 3, for example.

By providing the mirror 61 to the dial unit 1, the user of the dial unit 1 can not only visually recognize the direct visual recognition area 8c but also visually recognize the image of the visual recognition area 8c reflected on the mirror surface 61a of the mirror 61. can also visually recognize the visual recognition area 8c. This makes it easier to visually recognize the visual recognition area 8c.

Although not shown, dial unit 1 with transparent portion 6 fixed on input surface 8a as shown in FIG. In this case, the mirror 61 is arranged between the inner surface 3b of the dial outer shell 3 and the surface of the transparent portion 6 fixed on the input surface 8a. Also, in this case, the mirror 61 may be fixed to the transparent portion 6 or may be fixed to the dial outer body 3 .

8a to 10b show an example in which the transparent portion 6 is arranged inside the through hole 36 of the dial outer body 3 having the inner inclined surface 34. The transparent portion 6 may be arranged inside the through hole 36 of the body 3 .

<Fourth Embodiment>
Next, an input system 100 according to a fourth embodiment will be described. In addition, in the input system 100 according to the fourth embodiment, the parts that can be configured in the same manner as the input system 100 according to the above-described first to third embodiments are the same as those in the above-described first to third embodiments. The same reference numerals as those used for the corresponding portions in 1 are used, and overlapping descriptions are omitted.

FIG. 11 is a cross-sectional view showing an example of the input system 100 according to the fourth embodiment. According to the input system 100 according to the fourth embodiment, as in the input system 100 according to the first to third embodiments, the user pinches the dial outer body 3 of the dial unit 1 to open the support portion 5 . By rotating with respect to , the electrode 4 is rotated with respect to the touch panel 8 . By causing the input surface 8 a of the touch panel 8 to detect the rotation of the electrode 4 , rotation information can be input to the touch panel 8 .

As shown in FIG. 11, the touch panel 8 includes a body portion 81 having an installation surface 81a on which the dial unit 1 is provided, a decorative sheet 82 provided in an area of the installation surface 81a other than the area where the dial unit 1 is provided, have The decorative sheet 82 is not provided in the area of the installation surface 81a where the dial unit 1 is provided. The decorative sheet 82 is a sheet provided on the installation surface 81 a from the viewpoint of improving the design of the touch panel 8 . The decorative sheet 82 is, for example, a sheet having unevenness on its surface to ensure designability. The decorative sheet 82 is, for example, a embossed sheet. The decorative sheet 82 may be fabric.

The operation of providing the decorative sheet 82 in the area other than the area in which the dial unit 1 is provided on the installation surface 81a will be described. From the viewpoint of improving the design of the touch panel 8, it may be required to provide the decorative sheet 82 on the installation surface 81a. In this case, if a decorative sheet 82 is provided on the installation surface 81a of the main body 81 and the dial unit 1 is provided on the decorative sheet 82, the presence of the decorative sheet 82 causes the dial unit 1 to rotate information. Input accuracy may be reduced. For example, unevenness on the surface of the decorative sheet 82 creates an uneven gap between the dial unit 1 and the main body 81, and this gap may reduce the accuracy of inputting rotation information. In order to ensure the accuracy of inputting rotation information regardless of the presence of the decorative sheet 82, the dial unit 1 needs to be adjusted in a complicated manner.

On the other hand, since the decorative sheet 82 is provided on the installation surface 81a in an area other than the area where the dial unit 1 is provided, it is possible to input the rotation information by the dial unit 1 while providing the decorative sheet 82 on the installation surface 81a. It is possible to suppress the deterioration of the accuracy of In addition, there is no need to make complicated adjustments to the dial unit 1 . Therefore, the dial unit 1 can be provided on the touch panel 8 while ensuring the design of the input system 100 by the decorative sheet 82 .

Note that FIG. 11 shows an example in which the touch panel 8 having the decorative sheet 82 is provided with the dial unit 1 in which the dial outer body 3 has the through hole 36 and the inner inclined surface 34 . However, the touch panel 8 having the decorative sheet 82 may be provided with the dial unit 1 in which the dial outer body 3 does not have the through hole 36 and the inner inclined surface 34 .

Various modifications can be made to the first to fourth embodiments described above. For example, each member of the input system 100 according to the first to fourth embodiments may be appropriately combined.

An example of modification will be described below with reference to the drawings. In the following description and the drawings used in the following description, the same reference numerals as those used for the corresponding portions in the above-described specific example are used for parts that can be configured in the same manner as in the above-described specific example, and redundant description is given. omitted.

(Modification 1)
The dial unit 1 in which the dial outer body 3 has the through hole 36 may include a dial top cover 71 provided on the opposite side of the dial outer body 3 from the input surface 8a, as shown in FIG. The dial upper surface cover 71 has transparency. The dial upper surface cover 71 can prevent dirt, dust, and the like from entering the through hole 36 and making it difficult to visually recognize the visual recognition area 8c. Further, as described above, the touch panel 8 may have a force sensor, and information may be input to the touch panel 8 by pressing the dial unit 1 . In this case, if the dial upper surface cover 71 is provided, the surface of the dial unit 1 touched by the user when pushing the dial unit 1 increases, so that the operation of pushing the dial unit 1 becomes easier.

The dial upper surface cover 71 is a low-reflection cover that suppresses reflection of light from the outside of the input system 100, for example. The low-reflection cover that suppresses light reflection has, for example, a lower light reflectance than the surface of the dial outer body 3 . In this case, it is suppressed that the light from the outside of the input system 100 is reflected on the dial upper surface cover 71 and the visual recognition area 8c becomes difficult to visually recognize.

The dial upper surface cover 71 may be a transparent design cover. In this case, the design applied to the dial upper surface cover 71 is not particularly limited as long as the dial upper surface cover 71 does not greatly hinder the visual recognition of the visual recognition area 8c. The dial upper surface cover 71 may be black or patterned.

FIG. 13 is a top view showing an example of a dial top cover 71, which is a design cover. A dial upper surface cover 71 shown in FIG. 13 is provided in the dial unit 1 in which the dial outer body 3 has the inner inclined surface 34 . The dial upper surface cover 71 may have a designed portion and a non-designed portion. In the example shown in FIG. 13, the dial upper surface cover 71 has a central first portion 71a, a second portion 71b surrounding the first portion 71a, and a third portion 71c surrounding the second portion 71b. The first portion 71a overlaps the through hole 36 in the direction d1 perpendicular to the input surface 8a. The second portion 71b overlaps the inner inclined surface 34 in the direction d1 perpendicular to the input surface 8a. The third portion 71c overlaps the upper surface 3d in the direction d1 perpendicular to the input surface 8a. In the case of FIG. 13, the first portion 71a may not be designed, and the second portion 71b and the third portion 71c may be designed. Also, different designs may be applied to the second portion 71b and the third portion 71c. Since the design is not applied to the first portion 71a, it is possible to secure visibility of the visual recognition area 8c while using the design cover.

(Modification 2)
The dial unit 1 having the through hole 36 in the dial outer body 3 may include an optical sheet 72 as shown in FIGS. 14 to 16 . The optical sheet 72 is arranged so as to at least partially overlap the viewing area 8c in the direction d1 normal to the input surface 8a. In the examples shown in FIGS. 14 to 16, the optical sheet 72 is arranged so as to cover the entire visual recognition area 8c when viewed from the direction d1 perpendicular to the input surface 8a.

The optical sheet 72 is, for example, a hologram sheet or a viewing angle control sheet. The characteristics of the optical sheet 72 are appropriately selected from the viewpoint of making the viewing area 8c sufficiently easy for the user to see. For example, the characteristics of the optical sheet 72 can be selected so that the visual recognition area 8c can be easily viewed even from an oblique direction. The characteristics of the optical sheet 72 can be selected particularly from the viewpoint of widening the above-described first area 8d and the 27° viewing area.

The arrangement of the optical sheet 72 is not particularly limited as long as the optical sheet 72 at least partially overlaps the visual recognition area 8c in the normal direction d1 of the input surface 8a. In the example shown in FIG. 14, the optical sheet 72 is fixed on the input surface 8a and positioned inside the through hole 36. In the example shown in FIG. In the example shown in FIG. 15 , the optical sheet 72 is fixed on the input surface 8 a and positioned between the dial outer body 3 , the electrodes 4 and the support portion 5 and the touch panel 8 . In the example shown in FIG. 16, the dial unit 1 comprises two optical sheets 72, a first sheet 72a and a second sheet 72b. The first sheet 72 a and the second sheet 72 b are fixed to the dial outer body 3 and positioned inside the through hole 36 .

In the example shown in FIGS. 14 and 15, the optical sheet 72 is fixed on the input surface 8a and therefore does not rotate as the dial outer body 3 rotates. In the example shown in FIG. 16 , the optical sheet 72 is fixed to the dial outer body 3 and rotates as the dial outer body 3 rotates.

From the following point of view, the optical sheet 72 is preferably fixed on the input surface 8a. By fixing the optical sheet 72 on the input surface 8a, the properties of the optical sheet 72 can be selected on the assumption that the optical sheet 72 does not rotate with respect to the input surface 8a. For example, when the input surface 8a is installed perpendicular to the horizontal plane, the input surface 8a is easily visible from a viewpoint shifted upward with respect to the front of the input surface 8a, but from a viewpoint shifted to the left or right. The characteristics of the optical sheet 72 can be selected so that the input surface 8a is difficult to see.

(Modification 3)
The surface of the dial outer body 3 may have a non-uniform design when viewed in the rotational direction d3 of the dial outer body 3 . As a result, when rotating the dial outer body 3, the user can visually grasp the rotation of the dial outer body 3 by observing the movement of the design in the rotational direction d3. In particular, even if it is difficult to grasp the rotation of the dial outer body 3 with the sense of the hand due to circumstances such as the user wearing gloves, the rotation of the dial outer body 3 can be visually grasped.

For example, by forming linear concave portions 37 or linear convex portions extending non-parallel to the rotational direction d3 on at least one or more of the inner surface 3b, the outer surface 3c, and the upper surface 3d of the dial outer casing 3, the dial outer casing 3 is A non-uniform design can be applied to the surface when viewed in the direction of rotation d3. The dial outer body 3 may have at least one of a plurality of linear concave portions 37 and a plurality of linear convex portions extending non-parallel to the rotational direction d3. The plurality of linear concave portions 37 and the plurality of linear convex portions may be arranged in the rotation direction d3.

An example of the dial outer body 3 according to Modification 3 will be described with reference to FIGS. 17 and 18. FIG. FIG. 17 shows the dial outer body 3 incorporated in the input system 100, which has an inner inclined surface 34 and a plurality of linear concave portions 37. The upper surface 3d side of the dial outer body 3 is the input surface 8a. 1 is a top view showing a state seen from a perpendicular direction d1 of FIG. FIG. 18 is a side view showing the appearance of the outer surface 3c side of the dial outer body 3 shown in FIG. 17 as seen from the radial direction d2. In the dial outer body 3 shown in FIGS. 17 and 18, a plurality of linear recesses 37 are provided on the inner inclined surface 34 of the inner surface 3b and the outer surface 3c. As shown in FIG. 17, when the upper surface 3d side of the dial outer casing 3 is viewed from the vertical direction d1, the linear recessed portion 37 provided on the inner inclined surface 34 is visible. Further, as shown in FIG. 18, when the outer surface 3c side of the dial housing 3 is viewed from the radial direction d2, the linear concave portion 37 provided on the outer surface 3c is visible. In the example shown in FIG. 17, the linear concave portion 37 visible when the upper surface 3d side of the dial outer body 3 is viewed from the normal direction d1 extends non-parallel to the rotational direction d3 and non-parallel to the radial direction d2. . In the example shown in FIG. 18, the linear recesses 37 visible when the outer surface 3c side of the dial outer body 3 is viewed from the radial direction d2 extend non-parallel to the rotational direction d3 and non-parallel to the perpendicular direction d1. ing.

FIG. 19 is a diagram showing an example of the dial outer body 3 incorporated in the input system 100 according to Modification 3, which is different from the examples shown in FIGS. 17 and 18 . Specifically, FIG. 19 is a side view showing the appearance of the outer surface 3c side of the dial outer body 3 having the outer inclined surface 35 and the plurality of linear recesses 37 as seen from the radial direction d2. In the dial outer body 3 shown in FIG. 19 , the plurality of linear recesses 37 are provided on the entire outer surface 3 c including the outer inclined surface 35 . In the example shown in FIG. 19 as well, the linear recesses 37 visible when the outer surface 3c side of the dial outer body 3 is viewed from the radial direction d2 extend non-parallel to the rotational direction d3 and non-parallel to the perpendicular direction d1. there is

FIG. 20 shows an example of the dial outer body 3 incorporated in the input system 100 according to Modification 3, showing an example different from the examples shown in FIGS. 17 and 18 and the example shown in FIG. FIG. 4 is a diagram showing; Specifically, FIG. 20 is a side view of the outer surface 3c side of the dial outer body 3 having the outer inclined surface 35 and the plurality of linear recesses 37 as seen from the radial direction d2. In the dial outer body 3 shown in FIG. 20 , the plurality of linear recesses 37 are provided on the entire outer surface 3 c including the outer inclined surface 35 . In the example shown in FIG. 20 as well, the linear recesses 37 visible when the outer surface 3c side of the dial housing 3 is viewed from the radial direction d2 extend non-parallel to the rotational direction d3 and non-parallel to the perpendicular direction d1. there is In the example shown in FIG. 20, the width of one linear recess 37 changes when viewed along the direction in which the linear recess 37 extends. Specifically, the width w9 in the rotation direction d3 of the linear recess 37 shown in FIG. 20 changes so as to become smaller as it approaches the upper surface 3d.

According to the linear concave portion 37 having the characteristics described above, the user can visually observe the movement of the linear concave portion 37 in the rotation direction d3 when rotating the dial case 3. Can detect rotation. In particular, it becomes easy to visually determine whether the dial outer body 3 is rotating clockwise or counterclockwise.

Further, as described above, the dial outer body 3 may have linear protrusions extending non-parallel to the rotation direction d3 instead of or together with the linear recesses 37 . As a result, the same effect as when the dial outer casing 3 has the linear concave portion 37 can be obtained. The description of the linear concave portion 37 in this specification also applies to the linear convex portion as long as there is no contradiction. The form of the linear concave portion 37 and the linear convex portion may be selected with the intention of exhibiting an effect other than the effect of facilitating the user's visual grasp of the rotation of the dial outer body 3 . For example, as the form of the linear concave portion 37 and the linear convex portion, a form that makes it difficult for the user's fingers to slip when pinching the dial outer body 3 may be selected.

(Modification 4)
The dial unit 1 may further include a decorative layer 38 that covers at least part of the dial outer body 3 . In the examples shown in FIGS. 21, 22 and 23, the decorative layer 38 covers the entire inner surface 3b, outer surface 3c and upper surface 3d of the dial outer body 3. As shown in FIG.

The material of the decorative layer 38 may be metal or resin. When the material of the decorative layer 38 is metal, the decorative layer 38 is a plated layer formed by plating, for example. When the material of the decorative layer 38 is metal, the decorative layer 38 may be a metal plate attached to the dial outer body 3 . The decorative layer 38 may be a coating applied by spraying or the like. The decorative layer 38 may be formed by integrally molding the dial outer body 3 and the decorative layer 38 by insert molding. The decorative layer 38 may be formed by integrally forming the dial outer body 3 and the decorative layer 38 by in-mold molding. Here, by using resin as the material of the dial outer body 3, particularly the material of the dial outer body main body 31 as described above, a decorative layer covering at least a part of the dial outer body 3 can be obtained by the various methods described above. 38 can be formed.

When the decorative layer 38 is formed by insert molding, the decorative layer 38 includes, for example, a decorative body layer that is provided on the dial outer body 3 and that is decorated, and a decorative body layer that is provided on the decorative body layer. and a base material layer that supports the decoration body layer and covers and protects the decoration body layer. In this case, the decorative layer 38 further includes a binder layer which is provided between the dial outer body 3 and the decorative main body layer to strengthen the bonding between the dial outer body 3 and the decorative main body layer by insert molding. may have. When the decorative layer 38 is formed by insert molding, the decorative layer 38 includes a base layer provided on the dial outer body 3 and supporting the decorative body layer, and a base layer provided on the base layer and used for the decoration. and an overcoat layer provided on the decoration body layer to cover and protect the decoration body layer. In this case, the decorative layer 38 further has a binder layer provided between the dial outer body 3 and the base material layer to strengthen the bonding between the dial outer body 3 and the base layer by insert molding. may The base layer, overcoat layer and binder layer when the decorative layer 38 is formed by insert molding are, for example, transparent resin layers.

When the decorative layer 38 is formed by in-mold molding, the decorative layer 38 is provided on the dial outer body 3 by being transferred onto the dial outer body 3 by, for example, in-mold molding, and decorated. It has a decorative body layer. In this case, the decorative layer 38 may further include an adhesion layer that is provided between the dial outer body 3 and the decorative main body layer to bring the dial outer body 3 and the decorative main body layer into close contact with each other. The contact layer is a heat-sealing layer used when the dial outer body 3 and the decoration body layer are adhered to each other by, for example, heat-sealing (heat-sealing).

In the examples shown in FIGS. 21, 22 and 23, the decorative layer 38 includes a decorative layer inner surface portion 38a covering the inner surface 3b of the dial outer casing 3 and a decorative layer outer surface portion covering the outer surface 3c of the dial outer casing 3. 38b. In the examples shown in FIGS. 21, 22 and 23, the decorative layer 38 further includes a decorative layer upper surface portion 38e that covers the upper surface 3d of the dial outer body 3. As shown in FIG. Here, the color of the decorative layer inner surface portion 38a and the color of the decorative layer outer surface portion 38b may be different.

In the example shown in FIG. 21 , the dial outer body 3 has an inner inclined surface 34 . Therefore, the decoration layer inner surface portion 38a includes a decoration layer inner surface first portion 38c that covers the inner inclined surface 34 and a decoration layer inner surface second portion 38d that covers the portion of the inner surface 3b where the inner inclined surface 34 is not formed. include. In this case, the color of the decoration layer inner surface first portion 38c and the color of the decoration layer inner surface second portion 38d may be the same or different. Further, in the example shown in FIG. 22 , the dial outer body 3 has an outer inclined surface 35 . Therefore, the decoration layer outer surface portion 38b includes a decoration layer outer surface first portion 38f that covers the outer inclined surface 35 and a decoration layer outer surface second portion 38g that covers a portion of the outer surface 3c where the outer inclined surface 35 is not formed. include. In this case, the color of the decorative layer outer surface first portion 38f and the color of the decorative layer outer surface second portion 38g may be the same or different. Further, in the example shown in FIG. 23 , the dial outer body 3 has neither the inner inclined surface 34 nor the outer inclined surface 35 . Also in this case, the decorative layer 38 can include a decorative layer inner surface portion 38a, a decorative layer outer surface portion 38b, and a decorative layer upper surface portion 38e. The color of the decorative layer upper surface portion 38e may be the same as at least one of at least a portion of the decorative layer inner surface portion 38a and at least a portion of the decorative layer outer surface portion 38b. The color of the decorative layer upper surface portion 38e may be different from both the decorative layer inner surface portion 38a and the decorative layer outer surface portion 38b.

Here, by using a resin as the material of the dial outer casing 3, particularly the material of the dial outer casing main body 31, the decorative layer 38 covering at least a portion of the dial outer casing 3 can be formed by the various methods described above. Therefore, by using resin as the material of the dial outer body 3, it becomes easy to make the color of the decorative layer 38 different for each part.

The color of the decorative layer outer surface portion 38b may be selected from the viewpoint of the design of the dial unit 1. In particular, the color of the decorative layer outer surface portion 38b when the dial outer casing 3 does not have the outer inclined surface 35 and the color of the decorative layer outer surface second portion 38g when the dial outer casing 3 has the outer inclined surface 35 are , may be selected from the viewpoint of design.

When the color of the decorative layer inner surface portion 38a and the color of the decorative layer outer surface portion 38b are different, the value of L ^* a ^* b ^* lightness L ^* in the color system of the decorative layer inner surface portion 38a It may be greater than the value of the lightness L ^* in the L ^* a ^* b ^* color system of the outer surface portion 38b. When the color of the decoration layer inner surface portion 38a is different for each portion and/or the color of the decoration layer outer surface portion 38b is different for each portion, the L ^* a ^* b ^* color system of the decoration layer inner surface portion 38a may be greater than the maximum value of lightness L ^* in the L ^* a ^* b ^* color system ^of the decorative layer outer surface portion 38b.

In this specification, the value of lightness L ^* in the L ^* a ^* b ^* color system is measured according to JIS Z8722:2009. Specifically, the value of the lightness L ^* in the L ^* a ^* b ^* color system of the object to be measured such as the decorative layer 38 can be measured by the following method. A sample is prepared by cutting the object to be measured into small pieces and cutting out a portion of the object. Next, the sample is pre-cooled under liquid nitrogen for 10 minutes using a freeze grinder (6870 Freezer/Mill manufactured by SPEX) and then freeze-ground for 10 minutes under liquid nitrogen to obtain a powder. Next, this powder is measured for the lightness L ^* value in the L ^* a ^* b ^* color system with reflected light using a spectral colorimeter (Murakami Color Research Laboratory Co., Ltd., CMS-35SP). . The measurement conditions are SCE (exclude specular reflection), 10° field of view, and D65 light source.

The value of the brightness L ^* of the decorative layer inner surface portion 38a is greater than the value of the brightness L ^* of the decorative layer outer surface portion 38b, so that the color of the decorative layer outer surface portion 38b is adjusted to the design properties required for the dial unit 1. The color of the decorative layer inner surface portion 38a can be made brighter while being freely set according to the condition. In addition, since the value of the brightness L ^* of the decorative layer inner surface portion 38a is larger than the value of the brightness L ^* of the decorative layer outer surface portion 38b, the light emitted from the visible region 8c and directed toward the decorative layer inner surface portion 38a is , are likely to be reflected at the decorative layer inner surface portion 38a. Therefore, the light emitted from the visual recognition area 8c is reflected and diffused by the decorative layer inner surface portion 38a. This makes it easy for the user to visually recognize the decorative layer inner surface portion 38a even when the environment around the dial unit 1 is dark. For example, when riding in a car equipped with the dial unit 1 at night, the user can easily see the decorative layer inner surface portion 38a when the inside of the car is dark. Therefore, even if the environment around the dial unit 1 is dark, the user can easily recognize the positions of the dial unit 1 and the visual recognition area 8c by visually recognizing the decorative layer inner surface portion 38a.

When the color of the decorative layer inner surface portion 38a and the color of the decorative layer outer surface portion 38b are different, the value of L ^* a ^* b ^* lightness L ^* in the color system of the decorative layer inner surface portion 38a It may be smaller than the value of the lightness L ^* in the L ^* a ^* b ^* color system of the outer surface portion 38b. When the color of the decoration layer inner surface portion 38a is different for each portion and/or the color of the decoration layer outer surface portion 38b is different for each portion, the L ^* a ^* b ^* color system of the decoration layer inner surface portion 38a may ^be smaller than the minimum value of the lightness L ^* in the L ^* a ^* b ^* color system of the decorative layer outer surface portion 38b.

Since the value of the lightness L ^* of the decorative layer inner surface portion 38a is smaller than the value of the lightness L ^* of the decorative layer outer surface portion 38b, the color of the decorative layer outer surface portion 38b is adjusted to the design properties required for the dial unit 1. The color of the decorative layer inner surface portion 38a can be made darker while being freely set according to the condition. Thus, the contrast difference between the visible area 8c surrounded by the decorative layer inner surface portion 38a and the decorative layer inner surface portion 38a can make the display of the visible area 8c relatively conspicuous.

At least part of the decorative layer 38 may be a part that reflects light. The material of the light-reflecting portion of the decorative layer 38 is, for example, metal. If the light-reflecting portion of the decorative layer 38 is made of metal, the light-reflecting portion of the decorative layer 38 may be a plated layer formed by plating. It may be an attached metal plate. Here, the light-reflecting portion of the decorative layer 38 has a higher light reflectance than the surface of the dial outer body 3 . The light-reflecting portion of the decorative layer 38 may be a portion having a light reflectance of 30% or more. In addition, the reflectance of light is measured as follows. First, a sample having a size of 20 mm×20 mm is cut out from an object to be measured such as the decorative layer 38 . Next, a black resin plate is adhered to the rear surface of the sample. Next, the surface of the sample is irradiated with light at an incident angle of 5°. At this time, the surface of the sample is irradiated with light having a wavelength of 550 nm. Then, using a spectrophotometer (manufactured by JASCO Corporation, V-7100), the light reflection spectrum is measured to calculate the light reflectance.

In the examples shown in FIGS. 21, 22 and 23, the decorative layer 38 covers the entire inner surface 3b, outer surface 3c and upper surface 3d of the dial outer body 3. 38 may not cover the entire inner surface 3b, outer surface 3c and upper surface 3d of the dial outer casing 3. That is, the decorative layer 38 may not include at least one of the portions of the decorative layer 38 shown in FIGS. 21, 22 and 23. FIG. In this case, the value of the lightness L ^* in the L ^* a ^* b ^* color system ^of the decorative layer 38 is higher than the value of the lightness L* in the L ^* a ^* b ^* color system of the surface of the dial outer body 3. may also contain large portions. The decorative layer 38 has a value of lightness L ^* in the L ^* a ^* b ^* color system smaller than the value of lightness L ^* in the L ^* a ^* b ^* color system of the surface of the dial outer body 3. may contain parts. Also, the decorative layer 38 may include a portion that reflects light.

Specifically, when the dial outer body 3 has the inner inclined surface 34 as shown in FIG. 21, the decorative layer 38 may include a decorative layer inner surface first portion 38c. The decorative layer 38 may not include portions other than the decorative layer inner surface first portion 38c.

When the dial outer casing 3 has the inner inclined surface 34 and the decorative layer 38 includes the decorative layer inner surface first portion 38c, the decorative layer inner surface first portion 38c has a value of lightness L ^* equal to that of the dial outer casing. It may be a portion smaller than the value of the lightness L ^* of the surface of the body 3 . As a result, the color of the decorative layer inner surface first portion 38c becomes darker, and the difference in contrast between the visible region 8c surrounded by the decorative layer inner surface first portion 38c and the decorative layer inner surface first portion 38c results in The display of the visual recognition area 8c can be relatively conspicuous.

When the dial outer casing 3 has the inner inclined surface 34 and the decorative layer 38 includes the decorative layer inner surface first portion 38c, the decorative layer inner surface first portion 38c has a value of lightness L ^* equal to that of the dial outer casing. It may be a portion of the surface of the body 3 that is greater than the value of the lightness L ^* . As a result, the color of the decoration layer inner surface first portion 38c becomes brighter. In addition, the light emitted from the visual recognition area 8c and directed toward the decorative layer inner surface first portion 38c is more likely to be reflected by the decorative layer inner surface first portion 38c. Therefore, the light emitted from the visual recognition area 8c is reflected and diffused by the decoration layer inner surface first portion 38c. This makes it easy for the user to visually recognize the decorative layer inner surface first portion 38c even when the environment around the dial unit 1 is dark. For example, when getting into a car in which the dial unit 1 is mounted at night, the user can easily see the decorative layer inner surface first portion 38c when the inside of the car is dark. Therefore, even when the environment around the dial unit 1 is dark, the user can easily recognize the positions of the dial unit 1 and the visual recognition area 8c by visually recognizing the decorative layer inner surface first portion 38c. .

When the dial outer body 3 has the inner inclined surface 34 and the decorative layer 38 includes the decorative layer inner surface first portion 38c, the decorative layer inner surface first portion 38c is a portion that reflects light. good. Thus, the light emitted from the visual recognition region 8c and directed toward the decoration layer inner surface first portion 38c is reflected and diffused by the decoration layer inner surface first portion 38c. This makes it easy for the user to visually recognize the decorative layer inner surface first portion 38c even when the environment around the dial unit 1 is dark. Therefore, even when the environment around the dial unit 1 is dark, the user can easily recognize the positions of the dial unit 1 and the visual recognition area 8c by visually recognizing the decorative layer inner surface first portion 38c. .

Further, when the dial outer body 3 has the inner inclined surface 34 as shown in FIG. 21, the decorative layer 38 may include a decorative layer upper surface portion 38e. The decorative layer 38 may not include portions other than the decorative layer upper surface portion 38e. When the dial outer casing 3 has the inner inclined surface 34 and the decorative layer 38 includes the decorative layer upper surface portion 38e, the decorative layer upper surface portion 38e has a value of lightness L ^* equal to that of the surface of the dial outer casing 3. It may be a portion larger than the value of the lightness L ^* of . As a result, the color of the decorative layer upper surface portion 38e becomes brighter. Therefore, it becomes easier for the user to visually recognize the decorative layer upper surface portion 38e. In particular, even when the surrounding environment of the dial unit 1 is dark, it becomes easy for the user to visually recognize the decorative layer upper surface portion 38e. Therefore, even if the environment around the dial unit 1 is dark, the user can easily recognize the positions of the dial unit 1 and the visual recognition area 8c by visually recognizing the decoration layer upper surface portion 38e.

Moreover, when the dial outer body 3 has the inner inclined surface 34 as shown in FIG. 21, the decorative layer 38 may include a decorative layer outer surface portion 38b. The decorative layer 38 may not include portions other than the decorative layer outer surface portion 38b. When the dial outer casing 3 has the inner inclined surface 34 and the decorative layer 38 includes the decorative layer outer surface portion 38b, the decorative layer outer surface portion 38b has a value of lightness L ^* equal to that of the surface of the dial outer casing 3. may be a portion smaller than the value of the lightness L ^* . Furthermore, irregularities may be formed on the surface of the decorative layer outer surface portion 38b. The unevenness formed on the surface of the decorative layer outer surface portion 38b prevents the user's fingers from slipping when the user picks up the dial outer body 3. As shown in FIG.

Further, when the dial outer body 3 has the inner inclined surface 34 as shown in FIG. 21, the decorative layer 38 may include a decorative layer inner surface second portion 38d. The decorative layer 38 may not include portions other than the decorative layer inner surface second portion 38d. When the dial outer casing 3 has the inner inclined surface 34 and the decorative layer 38 includes the decorative layer outer surface portion 38b, the decorative layer outer surface portion 38b has a value of lightness L ^* equal to that of the surface of the dial outer casing 3. may be a portion smaller than the value of the lightness L ^* .

Further, when the dial outer body 3 has the outer inclined surface 35 as shown in FIG. 22, the decorative layer 38 may include a decorative layer upper surface portion 38e. The decorative layer 38 may not include portions other than the decorative layer upper surface portion 38e. When the dial outer casing 3 has the outer inclined surface 35 and the decorative layer 38 includes the decorative layer upper surface portion 38e, the decorative layer upper surface portion 38e has a value of lightness L ^* equal to that of the surface of the dial outer casing 3. may be a portion smaller than the value of the lightness L ^* . As a result, the color of the decorative layer upper surface portion 38e becomes darker, and the contrast difference between the visible region 8c surrounded by the decorative layer upper surface portion 38e and the decorative layer upper surface portion 38e makes the visible region 8c relatively darker. can be made to stand out.

Further, when the dial outer body 3 has the outer inclined surface 35 and the decorative layer 38 includes the decorative layer upper surface portion 38e, the decorative layer upper surface portion 38e has a lightness L ^* value equal to that of the dial outer body 3 may be a portion greater than the value of the surface lightness L ^* . As a result, the color of the decorative layer upper surface portion 38e becomes brighter. Therefore, it becomes easier for the user to visually recognize the decorative layer upper surface portion 38e. In particular, even when the surrounding environment of the dial unit 1 is dark, it becomes easy for the user to visually recognize the decorative layer upper surface portion 38e. Therefore, even if the environment around the dial unit 1 is dark, the user can easily recognize the positions of the dial unit 1 and the visual recognition area 8c by visually recognizing the decoration layer upper surface portion 38e.

Further, when the dial outer body 3 has the outer inclined surface 35 and the decorative layer 38 includes the decorative layer upper surface portion 38e, the decorative layer upper surface portion 38e may be a portion that reflects light.

Further, when the dial outer body 3 has the outer inclined surface 35 as shown in FIG. 22, the decorative layer 38 may include a decorative layer outer surface first portion 38f. The decorative layer 38 may not include portions other than the decorative layer outer surface first portion 38f. When the dial outer casing 3 has the outer inclined surface 35 and the decorative layer 38 includes the decorative layer outer surface first portion 38f, the decorative layer outer surface first portion 38f has a value of lightness L ^* equal to that of the dial outer casing. It may be a portion smaller than the value of the lightness L ^* of the surface of the body 3 . Further, unevenness may be formed on the surface of the decorative layer outer surface first portion 38f. The irregularities formed on the surface of the decorative layer outer surface first portion 38f can prevent the user's fingers from slipping when the user pinches the dial outer body 3. As shown in FIG.

Further, when the dial outer body 3 has the outer inclined surface 35 and the decorative layer 38 includes the decorative layer outer surface first portion 38f, the decorative layer outer surface first portion 38f is a portion that reflects light. may

Further, when the dial outer body 3 has the outer inclined surface 35 as shown in FIG. 22, the decorative layer 38 may include a decorative layer outer surface second portion 38g. The decorative layer 38 may not include portions other than the decorative layer outer surface second portion 38g. When the dial outer casing 3 has the outer inclined surface 35 and the decorative layer 38 includes the decorative layer outer surface second portion 38g, the decorative layer outer surface second portion 38g has a value of lightness L ^* equal to that of the dial outer casing. It may be a portion smaller than the value of the lightness L ^* of the surface of the body 3 . This suppresses external light from being reflected on the second decorative layer outer surface portion 38g. Therefore, it is possible to prevent the outside light reflected by the decorative layer outer surface second portion 38g from entering the user's eyes and hindering the user's visual recognition of the visual recognition region 8c.

Further, when the dial outer body 3 has the outer inclined surface 35 and the decorative layer 38 includes the decorative layer outer surface second portion 38g, the decorative layer outer surface second portion 38g is a portion that reflects light. may

Further, when the dial outer body 3 has the outer inclined surface 35 as shown in FIG. 22, the decorative layer 38 may include a decorative layer inner surface portion 38a. The decorative layer 38 may not include portions other than the decorative layer inner surface portion 38a. When the dial outer body 3 has the outer inclined surface 35 and the decorative layer 38 includes the decorative layer inner surface portion 38a, the decorative layer inner surface portion 38a has a value of lightness L ^* equal to that of the surface of the dial outer body 3. may be a portion smaller than the value of the lightness L ^* . As a result, the color of the decorative layer inner surface portion 38a becomes darker, and due to the difference in contrast between the visible region 8c surrounded by the decorative layer inner surface portion 38a and the decorative layer inner surface portion 38a, the visible region 8c becomes relatively darker. can be made to stand out.

Further, when the dial outer casing 3 has the outer inclined surface 35 and the decorative layer 38 includes the decorative layer inner surface portion 38a, the decorative layer inner surface portion 38a has a lightness L ^* value equal to that of the dial outer casing 3 may be a portion greater than the value of the surface lightness L ^* . This makes the color of the decorative layer inner surface portion 38a brighter. Further, the light emitted from the visible region 8c and directed toward the decorative layer inner surface portion 38a is reflected and diffused by the decorative layer inner surface portion 38a. Therefore, it becomes easier for the user to visually recognize the decorative layer inner surface portion 38a. In particular, even when the environment around the dial unit 1 is dark, the user can easily visually recognize the decorative layer inner surface portion 38a. Therefore, even if the environment around the dial unit 1 is dark, the user can easily recognize the positions of the dial unit 1 and the visual recognition area 8c by visually recognizing the decorative layer inner surface portion 38a.

Further, when the dial outer body 3 has the outer inclined surface 35 and the decorative layer 38 includes the decorative layer inner surface portion 38a, the decorative layer inner surface portion 38a may be a portion that reflects light. Thus, the light emitted from the visible region 8c and directed toward the decorative layer inner surface portion 38a is reflected and diffused by the decorative layer inner surface portion 38a. This makes it easy for the user to visually recognize the decorative layer inner surface portion 38a even when the environment around the dial unit 1 is dark. Therefore, even if the environment around the dial unit 1 is dark, the user can easily recognize the positions of the dial unit 1 and the visual recognition area 8c by visually recognizing the decorative layer inner surface portion 38a.

Further, when the dial outer body 3 does not have the inner inclined surface 34 and the outer inclined surface 35 as shown in FIG. 23, the decorative layer 38 may include a decorative layer upper surface portion 38e. The decorative layer 38 may not include portions other than the decorative layer upper surface portion 38e. When the dial outer casing 3 does not have the inner inclined surface 34 and the outer inclined surface 35 and the decorative layer 38 includes the decorative layer upper surface portion 38e, the decorative layer upper surface portion 38e has a lightness L ^* value of It may be a portion smaller than the value of the lightness L ^* of the surface of the dial outer body 3 . As a result, the color of the decorative layer upper surface portion 38e becomes darker, and the contrast difference between the visible region 8c surrounded by the decorative layer upper surface portion 38e and the decorative layer upper surface portion 38e makes the visible region 8c relatively darker. can be made to stand out.

Further, when the dial outer body 3 does not have the inner inclined surface 34 and the outer inclined surface 35 and the decorative layer 38 includes the decorative layer upper surface portion 38e, the decorative layer upper surface portion 38e has the value of lightness L ^* may be a portion of the surface of the dial outer body 3 that is greater than the value of the lightness L ^* . As a result, the color of the decorative layer upper surface portion 38e becomes brighter. Therefore, it becomes easier for the user to visually recognize the decorative layer upper surface portion 38e. In particular, even when the surrounding environment of the dial unit 1 is dark, it becomes easy for the user to visually recognize the decorative layer upper surface portion 38e. Therefore, even if the environment around the dial unit 1 is dark, the user can easily recognize the positions of the dial unit 1 and the visual recognition area 8c by visually recognizing the decoration layer upper surface portion 38e.

Further, when the dial outer body 3 does not have the inner inclined surface 34 and the outer inclined surface 35 and the decorative layer 38 includes the decorative layer upper surface portion 38e, the decorative layer upper surface portion 38e is a portion that reflects light. may be

Further, when the dial outer body 3 does not have the inner inclined surface 34 and the outer inclined surface 35 as shown in FIG. 23, the decorative layer 38 may include a decorative layer inner surface portion 38a. The decorative layer 38 may not include portions other than the decorative layer inner surface portion 38a. When the dial outer body 3 does not have the inner inclined surface 34 and the outer inclined surface 35 and the decorative layer 38 includes the decorative layer inner surface portion 38a, the decorative layer inner surface portion 38a has a lightness L ^* value of It may be a portion smaller than the value of the lightness L ^* of the surface of the dial outer body 3 . As a result, the color of the decorative layer inner surface portion 38a becomes darker, and due to the difference in contrast between the visible region 8c surrounded by the decorative layer inner surface portion 38a and the decorative layer inner surface portion 38a, the visible region 8c becomes relatively darker. can be made to stand out.

Further, when the dial outer body 3 does not have the inner inclined surface 34 and the outer inclined surface 35 and the decorative layer 38 includes the decorative layer inner surface portion 38a, the decorative layer inner surface portion 38a is a portion that reflects light. may be As a result, the light emitted from the visible region 8c and directed toward the decorative layer inner surface portion 38a is reflected and diffused by the decorative layer inner surface portion 38a. Therefore, even when the environment around the dial unit 1 is dark, the user can easily see the decorative layer inner surface portion 38a. Therefore, even if the environment around the dial unit 1 is dark, the user can easily recognize the positions of the dial unit 1 and the visual recognition area 8c by visually recognizing the decorative layer inner surface portion 38a.

Further, when the dial outer body 3 does not have the inner inclined surface 34 and the outer inclined surface 35 as shown in FIG. 23, the decorative layer 38 may include a decorative layer outer surface portion 38b. The decorative layer 38 may not include portions other than the decorative layer outer surface portion 38b. When the dial outer body 3 does not have the inner inclined surface 34 and the outer inclined surface 35 and the decorative layer 38 includes the decorative layer outer surface portion 38b, the decorative layer outer surface portion 38b has a lightness L ^* value of It may be a portion smaller than the value of the lightness L ^* of the surface of the dial outer body 3 . This suppresses external light from being reflected at the decorative layer outer surface portion 38b. Therefore, it is possible to prevent the outside light reflected by the decorative layer outer surface portion 38b from entering the user's eyes and hindering the user's visual recognition of the visual recognition region 8c.

Further, when the dial outer body 3 does not have the inner inclined surface 34 and the outer inclined surface 35 and the decorative layer 38 includes the decorative layer outer surface portion 38b, the decorative layer outer surface portion 38b is a portion that reflects light. may be

23, when the dial outer body 3 does not have the inner inclined surface 34 and the outer inclined surface 35, the decorative layer 38 includes a decorative layer inner surface portion 38a and a decorative layer upper surface portion 38e. It's okay. In this case, the decorative layer 38 may not include portions other than the decorative layer inner surface portion 38a and the decorative layer upper surface portion 38e. When the dial outer body 3 does not have the inner inclined surface 34 and the outer inclined surface 35 and the decorative layer 38 includes the decorative layer inner surface portion 38a and the decorative layer upper surface portion 38e, the decorative layer inner surface portion 38a is , the value of lightness L ^* may be smaller than the value of lightness L ^* of the surface of the dial outer body 3 . Also, the decorative layer upper surface portion 38e may be a portion that reflects light.

Further, when the dial outer body 3 does not have the inner inclined surface 34 and the outer inclined surface 35 and the decorative layer 38 includes the decorative layer inner surface portion 38a and the decorative layer upper surface portion 38e, the decorative layer inner surface portion 38a may be a portion that reflects light. Also, the decorative layer upper surface portion 38 e may be a portion in which the value of brightness L ^* is smaller than the value of brightness L ^* of the surface of the dial outer casing 3 . In this case, the decorative layer upper surface portion 38e has a lower lightness L ^* value than the surface lightness L ^* value of the dial outer body 3, so that the decorative layer upper surface portion 38e has a darker color. become. Thereby, the display of the visual recognition area 8c can be made relatively conspicuous due to the difference in contrast between the visual recognition area 8c surrounded by the decorative layer top surface portion 38e and the decorative layer top surface portion 38e.

(Modification 5)
In each of the embodiments and modifications described above, the dial unit 1 in which the through hole 36 is provided in the dial outer body 3 has been described. However, the form of the dial outer body 3 is not limited to this. In the dial unit 1 shown in FIG. 24 , the through hole 36 is not provided in the dial outer body 3 .

The dial unit 1 shown in FIG. 24 is also a dial unit laminated on the capacitive touch panel 8, like the dial unit 1 described above in each of the above-described embodiments and modifications. The dial unit 1 includes a support portion 5 fixed on the touch panel 8, a dial outer body 3 rotatably supported by the support portion 5, and rotatable in conjunction with the rotation of the dial outer body 3. an electrode 4 for generating capacitance.

The dial outer body main body 31 of the dial outer body 3 of Modified Example 5 has an additional portion that closes the through hole 36 in addition to the dial outer body main body 31 provided with the through hole 36 described in each of the above-described embodiments and modified examples. Equivalent to the one with A portion of the dial outer body main body 31 of Modified Example 5 corresponding to the dial outer body main body 31 provided with the through holes 36 described above in each of the above-described embodiments and modified examples is referred to as a main body first portion 311 . The description of the dial outer body main body 31 provided with the through hole 36 described above in each of the above-described embodiments and modifications can be applied to the description of the main body first portion 311 of Modification 5 as long as there is no contradiction. For example, at least the inner inclined surface 34 or the outer inclined surface 35 of the dial outer body main body 31 provided with the through hole 36 described in each of the embodiments and modifications described above is provided in the main body first portion 311 of Modification 5. An inclined surface similar to either one may be provided. That is, an inclined surface similar to the inner inclined surface 34 of the dial outer body main body 31 provided with the through hole 36 described in each of the above-described embodiments and modifications is provided on the inner surface of the main body first portion 311 of Modification 5. may be provided. Further, the outer surface of the main body first portion 311 of Modification 5 is provided with the through hole 36 described above in each of the above-described embodiments and modifications. may be provided. In this case, the description of the angle of inclination, dimensions, etc. regarding the inner inclined surface 34 or the outer inclined surface 35 can be applied to the explanation of the inclined surface provided in the main body first portion 311 of Modified Example 5 as long as there is no contradiction. In the example shown in FIG. 24, the first body portion 311 has an annular shape. Further, a portion of the dial outer body main body 31 of Modification 5 corresponding to the additional portion that closes the through hole 36 is referred to as a main body second portion 312 . In the example shown in FIG. 24, the main body first portion 311 is a plate-like portion parallel to the input surface 8a. The first body portion 311 and the second body portion 312 are integrally molded. In the example shown in FIG. 24 , the upward concave portion 33 is formed in the dial outer body 3 by having the dial outer body main body 31 having the main body first portion 311 and the main body second portion 312 . The rotation axis O<b>1 passes through the upward concave portion 33 .

The dial outer body main body 31 of Modification 5 has transparency. In the example shown in FIG. 24, the surface of the main body first portion 311 other than the surface facing the input surface 8a is covered with the decorative layer 38. As shown in FIG. As an example, the decorative layer 38 does not have transparency. The second body portion 312 is not covered with the decorative layer 38 . In this case, the portion of the input surface 8a that overlaps with the transparent second body portion 312 that is not covered with the decorative layer 38 can be used as an area 8f in which the user can visually recognize the input surface 8a.

It is also possible to appropriately combine a plurality of constituent elements disclosed in the above embodiments and modifications as necessary. Alternatively, some constituent elements may be deleted from all the constituent elements shown in the above embodiments and modifications.

Reference Signs List 1 dial unit 2 dial component 3 dial outer body 3b inner surface 3c outer surface 34 inner inclined surface 35 outer inclined surface 36 through hole 4 electrode 41 detection electrode portion 42 parasitic capacitance generating electrode portion 43 connecting portion 5 support portion 5a convex portion 6 transparent portion 71 Dial upper surface cover 72 Optical sheet 8 Touch panel 8a Input surface 8c Visible area 8d First area 8e Second area 81 Main body 81a Installation surface 82 Decorative sheet 9 Display device 100 Input system

Claims (24)

A dial unit provided on the input surface of a capacitive touch panel for inputting rotation information to the touch panel,
a support fixed on the input surface;
a dial exterior body rotatably supported by the support portion and provided with a through hole;
an electrode fixed to the dial outer body and detected on the input surface of the touch panel;
at least a portion of the input surface is visible through the through hole;
The dial outer body includes an insulating material,
The dial unit, wherein the dial outer body covers the electrodes on the input surface. At least part of the outer surface of the dial outer body is inclined so as to increase the width of the dial outer body in the direction horizontal to the input surface as it approaches the input surface, and/or the dial outer body 2. The dial unit according to claim 1, wherein at least part of the inner surface is inclined so as to reduce the width of said through-hole in a direction horizontal to said input surface as said input surface is approached. The area of the region on the input surface that is visible through the through-hole from any direction forming an angle of 27° or less with respect to the normal to the input surface is the area that is visible through the through-hole from a direction perpendicular to the input surface. 3. A dial unit according to claim 2, which is 80% or more of the possible area of the input surface. The electrodes include a sensing electrode portion sensed on the input surface, a parasitic capacitance generating electrode portion separated from the input surface and the sensing electrode portion, and a connection connecting the sensing electrode portion and the parasitic capacitance generating electrode portion. 2. The dial unit of claim 1, comprising: a. 5. The dial unit according to claim 4, wherein said electrode having said detection electrode portion, said parasitic capacitance generating electrode portion, and said connecting portion is formed of an integral metal plate. at least a part of the outer surface of the dial outer body is inclined so as to increase the width of the dial outer body in a direction horizontal to the input surface as it approaches the input surface;
In a radial direction perpendicular to the axis of rotation of the dial outer body with respect to the support, the sensing electrode portion is located on the opposite side of the connecting portion to the axis of rotation,
5. The dial unit according to claim 4, wherein said parasitic capacitance generating electrode portion is located on said rotational axis side of said connecting portion in said radial direction. at least part of the inner surface of the dial outer body is inclined so as to reduce the width of the through-hole in a direction horizontal to the input surface as it approaches the input surface;
In a radial direction perpendicular to the rotation axis of the dial outer body rotating with respect to the support part, the detection electrode part is positioned on the rotation axis side of the connecting part,
5. The dial unit according to claim 4, wherein said parasitic capacitance generating electrode portion is located on the opposite side of said connecting portion from said rotational axis in said radial direction. 2. The dial unit according to claim 1, further comprising a transparent portion at least partially disposed inside said through hole. 9. The dial unit according to claim 8, wherein said transparent portion includes a resin material, and said transparent portion has a refractive index greater than 1.4 and less than 1.6. The transparent part is arranged apart from the dial outer body,
9. The dial unit according to claim 8, wherein said dial outer body is relatively movable with respect to said transparent portion. 9. The dial unit according to claim 8, wherein said transparent portion is fixed to said dial outer body. 2. The dial unit according to claim 1, further comprising a decorative layer covering at least part of said dial outer body. The decorative layer includes a decorative layer inner surface portion covering the inner surface of the dial outer casing and a decorative layer outer surface portion covering the outer surface of the dial outer casing,
13. The dial unit according to claim 12, wherein the color of the inner surface portion of the decorative layer and the color of the outer surface portion of the decorative layer are different. The value of the lightness L ^* in the L ^* a ^* b ^* color system of the inner surface portion of the decoration layer is greater than the value of the lightness L ^* in the L ^* a ^* b ^* color system of the outer surface portion of the decoration layer. 14. A dial unit according to claim 13. The value of the lightness L ^* in the L ^* a ^* b ^* color system of the inner surface portion of the decoration layer is smaller than the value of the lightness L ^* in the L ^* a ^* b ^* color system of the outer surface portion of the decoration layer. 14. A dial unit according to claim 13. A dial unit provided on the input surface of a capacitive touch panel for inputting rotation information to the touch panel,
a support fixed on the input surface;
a dial exterior body rotatably supported by the support portion and provided with a through hole;
an electrode fixed to the dial outer body and detected on the input surface of the touch panel;
at least a portion of the input surface is visible through the through hole;
A dial unit, further comprising a transparent portion, at least a portion of which is arranged inside the through hole. A dial unit laminated on a capacitive touch panel,
a support fixed on the touch panel;
a dial outer body rotatably supported by the support;
an electrode that is rotatable in conjunction with the rotation of the dial outer body and generates a capacitance,
The dial outer body includes an insulating material,
The dial unit, wherein the dial outer body covers the electrodes on the touch panel. An input system comprising the dial unit according to any one of claims 1 to 16 and the touch panel. When the angle formed by the direction in which the luminance of the input surface is half the value when viewed from the direction perpendicular to the input surface and the normal to the input surface is defined as the half-value width angle, the angle is formed with respect to the normal to the input surface. The area of the region on the input surface that is visible through the through hole from any direction whose angle is equal to or less than the half width angle is the area on the input surface that is visible through the through hole from a direction perpendicular to the input surface. 19. The input system of claim 18, which is 80% or more of the area of the region. 19. The input according to claim 18, wherein the touch panel has a body portion having an installation surface on which the dial unit is provided, and a decorative sheet provided on an area of the installation surface other than the area on which the dial unit is provided. system. An input system comprising a capacitive touch panel and a dial unit provided on an input surface of the touch panel for inputting rotation information to the touch panel,
The dial unit includes a support portion fixed on the input surface of the touch panel, a dial outer body rotatably supported by the support portion, and a dial outer body fixed to the dial outer body and detected on the input surface of the touch panel. and an electrode that is
The input system, wherein the touch panel includes a main body portion having an installation surface on which the dial unit is provided, and a decorative sheet provided on an area of the installation surface other than the area on which the dial unit is provided. A dial part of a dial unit that is provided on the input surface of a capacitive touch panel and inputs rotation information to the touch panel,
a dial outer body rotatably supported by a support portion fixed on the input surface and provided with a through hole;
an electrode fixed to the dial outer body and detected on the input surface of the touch panel;
at least a portion of the input surface is visible through the through hole;
The dial outer body includes an insulating material,
A dial component, wherein the dial outer body covers the electrodes on the input surface. At least part of the outer surface of the dial outer body is inclined so as to increase the width of the dial outer body in the direction horizontal to the input surface as it approaches the input surface, and/or the inner surface of the dial outer body. 23. The dial part according to claim 22, wherein at least a part of is inclined so as to reduce the width of said through-hole in a direction horizontal to said input surface as said input surface is approached. A dial outer body of a dial unit that is provided on the input surface of a capacitive touch panel and inputs rotation information to the touch panel,
The dial outer body is rotatably supported by a support fixed on the input surface, an electrode to be detected on the input surface of the touch panel is fixed to the dial outer body, and the dial outer body is penetrated. holes are provided,
at least a portion of the input surface is visible through the through hole;
At least part of the outer surface of the dial outer body is inclined so as to increase the width of the dial outer body in the direction horizontal to the input surface as it approaches the input surface, and/or the inner surface of the dial outer body. at least a part of which is inclined so as to reduce the width of the through-hole in the direction horizontal to the input surface as it approaches the input surface.

Images