Information
-
Patent Grant
-
6621016
-
Patent Number
6,621,016
-
Date Filed
Tuesday, April 30, 200222 years ago
-
Date Issued
Tuesday, September 16, 200321 years ago
-
Inventors
-
Original Assignees
-
Examiners
Agents
- Beyer Weaver & Thomas, LLP
-
CPC
-
US Classifications
Field of Search
US
- 200 4
- 200 5 R
- 200 11 R
- 200 11 D
- 200 11 DA
- 200 18
- 200 336
-
International Classifications
-
Abstract
In a complex operation input device according to the invention, a rotary electrical part manipulated with an operating member and a double-action push switch unit are arranged in a layered state in a direction of a rotation axis of the rotary electrical part. As a result, the device can be reduced in lateral size, and therefore it is made possible to provide a complex operation input device which can be used with a portable digital camera particularly suitably.
Description
BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates to a complex operation input device that can be suitably used with a digital camera or the like.
2. Description of the Prior Art
To describe the configuration of a complex operation input device according to the prior art with reference to FIG.
10
and
FIG. 11
, a fixed member
52
is fitted above a housing
51
, which is a molded synthetic resin item.
An insulating substrate
53
is fitted to the housing
51
so as to cover a receptacle
51
a
provided in the housing
51
, and over this insulating substrate
53
is mounted a first flexible insulating substrate
54
having a plurality of fixed contacts (not shown).
A movable contact
55
consisting of a leaf spring, in a state of opposing fixed contacts provided on the first flexible insulating substrate
54
, is mounted on the first flexible insulating substrate
54
. As the upper part of the movable contact
55
is pressed and reversed, the movable contact
55
comes into contact with one of the fixed contacts. These fixed contacts and movable contact
55
constitute a first push switch part S
3
.
A second flexible insulating substrate
56
provided with a fixed contact (not shown) is arranged so as to cover the upper part of the movable contact
55
, and the fixed contact provided on this second flexible insulating substrate
56
is connected by a communicating means (not shown) to the fixed contacts provided on the first flexible insulating substrate
54
.
A holding member
57
, which is a molded synthetic resin item, has a plate
57
a
and a cylindrical shaft
57
b
provided over this plate
57
a
, and this holding member
57
, in a state in which its plate
57
a
is accommodated in the receptacle
51
a
, is rotatably held by pressing the shaft
57
b
through the fixed member
52
.
A rubber contact
58
provided with a contact point is fitted within the shaft
57
b
so as to oppose the fixed contact provided on the second flexible insulating substrate
56
.
When the upper part of the rubber contact
58
is suppressed, the rubber contact
58
is bent to come into contact with the fixed contact provided on the second flexible insulating substrate
56
. These fixed contact and rubber contact
58
constitute a second push switch part S
4
.
As a result, the first and second push switch parts S
3
and S
4
constitute a two-stage suppressive switching section P
2
, and the first and second push switch parts S
3
and S
4
constituting this two-stage suppressive switching section P
2
are arranged in a layered state in the direction of the rotation axis G
2
of the holding member
57
.
In the two-stage suppressive switching section P
2
, first the rubber contact
58
is pressed to operate the second push switch part S
4
, and its continued pressing causes the movable contact
55
to be suppressed to operate the first push switch part S
3
.
A slider
59
consisting of a metal plate is fitted to the plate
57
a
in a position outer than the two-stage switching section P
2
in the radial direction, and this slider
59
comes into sliding contact with the fixed contact provided on the first flexible insulating substrate
54
. These fixed contact and slider
59
constitute a rotary electrical part D
2
.
This rotary electrical part D
2
is arranged in a radial direction orthogonal to the rotation axis G
2
of the two-stage suppressive switching section P
2
.
A lever
60
, which is a molded synthetic resin item, has a holder
60
a
and an arm
60
b
extending in one direction from this holder
60
a
. This lever
60
, in a state of being linked so as to rotate the holding member
57
, is arranged over the fixed member
52
.
A key top
61
arranged to be able to suppress the rubber contact
58
, in a state in which it is prevented from coming off by the holder
60
a
of the lever
60
, is fitted to be shiftable in the direction of the rotation axis G
2
.
A button
63
, which is a molded synthetic resin item elastically pressed by a coil spring
62
, is fitted to be vertically movable in a state in which it is prevented from coming off by the arm
60
b
of the lever
60
. This button
63
is provided with a projection
63
a,
which can be engaged with and disengaged from the fixed member
52
. When the button
63
is suppressed against the coil spring
62
, the projection
63
a
can come off a hole
52
a
of the fixed member
52
to enable the lever
60
to rotate.
A spring
64
fixed to the rotatable holding member
57
can be engaged with and disengaged from the insulating substrate
53
to form a detent mechanism, so that, when the holding member
57
rotates, the spring
64
engages with or disengages from the insulating substrate
53
to give a sense of click to the rotary action of the holding member
57
and the lever
60
.
To describe the operation of the conventional complex operation input device having such a configuration, first, when the key top
61
is suppressed in the direction of the rotation axis G
2
, the rubber contact
58
is pressed, and the second push switch part S
4
is manipulated. When the key top
61
is further suppressed, the rubber contact
58
suppresses the movable contact
55
via the second flexible insulating substrate
56
, and the first push switch part S
3
is manipulated.
Then, when released from suppression by the key top
61
, the movable contact
55
and the rubber contact
58
automatically return to their respective original states by their own elasticity, and the key top
61
returns to its own original state with the return of the rubber contact
58
.
Next, when the button
63
is suppressed against the coil spring
62
, the projection
63
a
is disengaged from the fixed member
52
to enable the lever
60
to turn, and if in this state the lever
60
is turned with the arm
60
b
, the holding member
57
will rotate to turn the slider
59
, which comes into sliding contact with the fixed contact on the first flexible insulating substrate
54
to cause the rotary electrical part D
2
to be operated.
Then, the spring
64
engages with or disengages from the insulating substrate
53
to cause the lever
60
to turn with a sense of click.
Or if the lever
60
is released from rotation, the lever
60
and the holding member
57
will be stopped by the detent mechanism where they have turned by a prescribed angle and, if in this position the button
63
is released from suppression, the button
63
will be pushed back by the coil spring
62
to enter into a state in which the fixed member
52
is engaged with the hole
52
a.
Such manipulations cause the complex operation input device to be operated.
The complex operation input device according to the prior art, in which the two-stage suppressive switching section P
2
and the rotary electrical part D
2
are arranged in the radial direction orthogonal to the direction of the rotation axis G
2
, has a large dimension in the lateral direction, and accordingly involves a problem of allowing no size reduction in the radial direction.
Especially, there is a problem that the device is unsuitable for portable items, such as a digital camera.
There is another problem that, on account of the use of the mutually separate first and second flexible insulating substrates
54
and
56
, not only is an extra task of electrically connecting them needed but also their incorporation is troublesome, resulting in poor productivity.
Still another problem is that, as the second flexible insulating substrate
56
provided with the fixed contact for the second push switch part S
4
is mounted over the movable contact
55
of the first push switch part S
3
and, moreover, the movable contact
55
is deformed in a state in which the rubber contact
58
is in contact with the fixed contact, the contact of the second push switch part S
4
is destabilized.
SUMMARY OF THE INVENTION
Therefore, an object of the present invention is to provide a complex operation input device which permits a size reduction in the lateral direction, provides high productivity and stabilizes the contact of the double-action push switch unit.
A first means to solve the problems noted above has a configuration provided with an operating member, a rotary electrical part manipulated with the operating member and a double-action push switch unit manipulated with the operating member, wherein the rotary electrical part and the double-action push switch unit are arranged in a layered state in a direction of a rotation axis of the rotary electrical part.
A second means to solve the problems noted above has a configuration wherein the operating member comprises a rotatable knob and a key top shiftable in the direction of the rotation axis, the rotary electrical part is operated by rotation of the knob and the double-action push switch unit is operated,by shifting of the key top.
A third means to solve the problems noted above has a configuration wherein the knob is annularly shaped and arranged so as to surround an outer circumference of the key top.
A fourth means to solve the problems noted above has a configuration wherein the double-action push switch unit comprises two, first and second, push switch parts differing from each other in operating force, a carrier member is provided to support the double-action push switch unit, the carrier member has a plate, and over the plate the first and second push switch parts are arranged in a layered state in the direction of the rotation axis.
A fifth means to solve the problems noted above has a configuration wherein the first and second push switch parts click by operating forces differing from each other.
A sixth means to solve the problems noted above has a configuration further provided with a driver arranged between the key top and the carrier member and capable of shifting in the direction of the rotation axis, wherein the first and second push switch parts are arranged above and underneath the driver, one above and the other underneath, with this driver in between.
A seventh means to solve the problems noted above has a configuration wherein one of the first and second push switch parts is supported over the plate, the other of the first and second push switch parts is supported over the driver, the one suppressive switching unit supported by the plate is operated by the driver, and the other suppressive switching unit supported by the driver is operated by the key top.
An eighth means to solve the problems noted above has a configuration wherein the carrier member is provided with a guide for guiding the shifting of the driver in the direction of the rotation axis.
A ninth means to solve the problems noted above has a configuration wherein the first and the suppressive switching units comprise one flexible insulating substrate provided with fixed contacts for the first and second push switch parts and movable contacts for the first and second push switch parts, to be engaged with and disengaged from the fixed contacts, the bending of the flexible insulating substrate causes it to be mounted over the plate or the driver, one of the first and second push switch parts is arranged between the key top and the driver, and the other is arranged between the driver and the plate.
A tenth means to solve the problems noted above has a configuration wherein the double-action push switch unit and the rotary electrical part are arranged on different sides of the plate of the carrier member, and the double-action push switch unit is positioned toward the key top.
An eleventh means to solve the problems noted above has a configuration wherein the rotary electrical part is provided with a rotor rotating together with the knob, a slider provided on this rotor, and a conducting pattern provided on a flexible insulating substrate, the slider coming into sliding contact with the conducting pattern, and fixed contacts for the first and second push switch parts are formed over the flexible insulating substrate.
A twelfth means to solve the problems noted above has a configuration further provided with a supporting member for supporting the carrier member, wherein the flexible insulating substrate mounted over the supporting member is held between the supporting member and the carrier member.
A thirteenth means to solve the problems noted above has a configuration wherein the rotor is arranged between the plate of the carrier member and the supporting member, side walls provided on the rotor are in contact with or close to part of the flexible insulating substrate positioned on an outer circumference of the conducting pattern to prevent the flexible insulating substrate from floating off.
A fourteenth means to solve the problems noted above has a configuration wherein the plate of the carrier member has a shaft provided in its central part and a plurality of projections protruding from the tip of the shaft in the direction of the rotation axis, the shaft is pressed through a hole bored in the rotor to rotatably support the rotor and the knob, and the projections are pressed through holes bored in the flexible insulating substrate and the supporting member to fit the carrier member to the supporting member.
A fifteenth means to solve the problems noted above has a configuration wherein the flexible insulating substrate is held between the tip of the shaft and the supporting member.
A sixteenth means to solve the problems noted above has a configuration wherein a forcing member intervenes between the carrier member and the rotor and/or the knob and, when the rotor has rotated via the knob, the rotor is returned to its initial position by the forcing member.
A seventeenth means to solve the problems noted above has a configuration wherein a stopper to limit a range of rotation of the rotor is provided between the carrier member and the rotor and/or the knob.
An eighteenth means to solve the problems noted above has a configuration wherein the rotary electrical part has a detent mechanism and, when the knob is rotated, the knob turns with articulation.
A nineteenth means to solve the problems noted above has a configuration wherein the detent mechanism is arranged within the rotor.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1
is a plan of a complex operation input device, which is a first preferred embodiment of the present invention;
FIG. 2
is a section along line
2
—
2
in
FIG. 1
;
FIG. 3
shows an exploded perspective view of the complex operation input device, which is the first preferred embodiment of the invention;
FIG. 4
illustrates how a rotor and a knob are coupled to each other and how a driver is guided in the complex operation input device, which is the first preferred embodiment of the invention;
FIG. 5
shows the under side of the rotor pertaining to the complex operation input device embodying the invention in the first mode, illustrating how a slider is fitted;
FIG. 6
shows the operation of the complex operation input device embodying the invention in the first mode, illustrating the state of its initial position;
FIG. 7
shows the operation of the complex operation input device embodying the invention in the first mode, illustrating the state of its operation;
FIG. 8
shows a development of a flexible insulating substrate in the complex operation input device embodying the invention in the first mode.
FIG. 9
shows a section of the essential part of a complex operation input device, which is a second preferred embodiment of the invention;
FIG. 10
shows a plan of the complex operation input device according to the prior art; and
FIG. 11
shows a section of the essential part of the complex operation input device according to the prior art.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS
To explain drawings illustrating a complex operation input device according to the present invention,
FIG. 1
is a plan of a complex operation input device, which is a first preferred embodiment of the invention;
FIG. 2
is a section along line
2
—
2
in
FIG. 1
;
FIG. 3
shows an exploded perspective view of the complex operation input device, which is the first preferred embodiment of the invention;
FIG. 4
illustrates how a rotor and a knob are coupled to each other and how a driver is guided in the complex operation input device, which is the first preferred embodiment of the invention; and
FIG. 5
shows the under side of the rotor pertaining to the complex operation input device embodying the invention in the first mode, illustrating how a slider is fitted.
Further,
FIG. 6
shows the operation of the complex operation input device embodying the invention in the first mode, illustrating the state of its initial position;
FIG. 7
shows the operation of the complex operation input device embodying the invention in the first mode, illustrating the state of its operation;
FIG. 8
shows a development of a flexible insulating substrate in the complex operation input device embodying the invention in the first mode; and
FIG. 9
shows a section of the essential part of a complex operation input device, which is a second preferred embodiment of the invention.
Next will be described the configuration of a complex operation input device, which is the first preferred embodiment of the invention with reference to FIG.
1
through
FIG. 8. A
supporting member
1
consisting of a metal plate, synthetic resin or the like is planarly shaped, and in its central part has a plurality of holes
1
a
provided on the same circle.
A flexible insulating substrate
2
consisting of a sheet of insulating film, as shown in FIG.
3
and
FIG. 8
in particular, has a planar first base
2
a
; a first link
2
b
bent upward from this first base
2
a
; a planar second base
2
c
arranged, in a state of being linked to this first link
2
b
, opposite the first base
2
a
; a second link
2
d
bent upward from this second base
2
c
and positioned on the reverse side to the first link
2
b
with the second base
2
c
in between; a planar third base
2
e
arranged, in a state of being linked to this second link
2
d
, opposite the second base
2
c
; a third link
2
f
bent from this third base
2
e
and positioned on the reverse side to the second link
2
d
with the third base
2
e
in between; and a planar fourth base
2
g
arranged, in a state of being linked to this third link
2
f
, opposite the third base
2
e.
The first base
2
a
of the flexible insulating substrate
2
has a wide portion
2
h
and a drawer
2
j
linked to this wide portion
2
h
. The flexible insulating substrate
2
in the central part of the wide portion
2
h
has a plurality of holes
2
k
provided on the same circle, a hole
2
m
provided in the central part of the third base
2
e
, and a small hole
2
n
provided in the vicinity of the third link
2
f
of the fourth base
2
g.
On the surface of this flexible insulating substrate
2
, as illustrated in particular in
FIG. 8
, is drawn a wiring pattern
3
consisting of an electric conductor. This wiring pattern
3
has, in the position of the outer circumference of the holes
2
k
, a conducting pattern
3
a
provided on the first base
2
a
to constitute a fixed contact; a pair of first fixed contacts
3
b
provided on the second base
2
c
; and a pair of second fixed contacts
3
c
provided on the fourth base
2
g
. These first and second fixed contacts
3
b
and
3
c
are led to the drawer
2
j
by the wiring pattern
3
provided on the first, second and third links
2
b
,
2
d
and
2
f
and the first, second, third and fourth bases
2
a
,
2
c
,
2
e
and
2
g
, and the conducting pattern
3
a
is also led by the wiring pattern
3
to the wide portion
2
h.
Over the flexible insulating substrate
2
is provided an insulating film (insulating resist)
15
with the conducting pattern
3
a
, the first and second fixed contacts
3
b
and
3
c
, and the wiring pattern
3
partly exposed, and the conducting pattern
3
a
is exposed on the right and left with the insulating film
15
in the middle.
In the flexible insulating substrate
2
being configured in this way, the holes
2
k
are matched with the holes
1
a
of the supporting member
1
and, with the conducting pattern
3
a
directed upward, the first base
2
a
is mounted over the supporting member
1
.
A carrier member
4
, which is a molded synthetic resin item, has a flat plate
4
a
, a cylindrical shaft
4
b
protruding downward from this plate
4
a
, a plurality of projections
4
c
projecting downward from the tip of this shaft
4
b
, three stubs
4
d
provided on the under face of the plate
4
a
to surround the shaft
4
b
at intervals, a guide
4
e
consisting of two holes penetrating the plate
4
a
, and a stopper
4
f
consisting of a convex protruding in the radial direction from the outer circumference of the plate
4
a.
This carrier member
4
presses the projections
4
c
through the holes
2
k
of the flexible insulating substrate
2
and the holes
1
a
of the supporting member
1
, and the tips of the projections
4
c
are heat-caulked to fit the carrier member
4
to the supporting member
1
.
In this arrangement, the first base
2
a
of the flexible insulating substrate
2
is supported by being held between the tip of the shaft
4
b
and the supporting member
1
to prevent the first base
2
a
from floating off the supporting member
1
.
A rotor
5
, which is a molded synthetic resin item, has a disk-shaped base
5
a
, a hole
5
b
provided in the central part of this base
5
a
, a plurality of arcwise side walls
5
c
protruding downward from the outer circumference of the base
5
a
, a plurality of cuts
5
d
provide between these side walls
5
c
, a plurality of arcwise walls
5
e
protruding upward from the outer circumference of the base
5
a
, a plurality of grooves
5
f
provided between these walls
5
e
, a plurality of projections
5
g
protruding outward from the outer faces of the walls
5
e
, an engaging piece
5
h
(see FIG.
6
and
FIG. 7
) consisting of one convex projecting outward from the outer face of one of the walls
5
e
, a plurality of stubs
5
j
projecting downward from the lower face of the base
5
a
, and a plurality of engaging stubs
5
k
(see FIG.
6
and
FIG. 7
) projecting upward at intervals on the upper face of the base
5
a.
This rotor
5
is fitted between the plate
4
a
of the carrier member
4
and the supporting member
1
to be rotatable around the shaft
4
b
, with the shaft
4
b
of the carrier member
4
being pressed through the hole
5
b.
When the rotor
5
is fitted, the tops of the stubs
4
d
come into contact with the upper face of the base
5
a
in a state in which the plate
4
a
is positioned within the walls
5
e
, with the result that a void
6
is formed between the plate
4
a
and the base
5
a
. At the same time, in a state in which the side walls
5
c
surround the conducting pattern
3
a
, the lower ends of the side walls
5
c
come into contact with or are positioned close to the first base
2
a
to prevent the flexible insulating substrate
2
from floating off.
Also, when the rotor
5
is fitted, the flexible insulating substrate
2
has a configuration that, in a state in which the bent first link
2
b
extends upward through the cuts
5
d
and the first fixed contact
3
b
faces upward, the second base
2
c
is mounted on the plate
4
a.
Further, when the rotor
5
is fitted, if the stopper
4
f
of the carrier member
4
is positioned in the grooves
5
f
of the rotor
5
, the rotation of the rotor
5
causes the walls
5
e
positioned in the grooves
5
f
to hit against the stopper
4
f
to limit the range of rotation of the rotor
5
.
A slider
7
consisting of a springy metal plate, as shown in
FIG. 5
in particular, is fitted to the rotor
5
by caulking by one of the stubs
5
j
in a state in which it is positioned on the under face of the base
5
a
of the rotor
5
so that it rotates together with the rotor
5
, and at the same time another of the stubs
5
j
, positioned in the central part of the slider
7
, determines the position of the slider
7
.
This slider
7
slides in contact with the conducting pattern
3
a
to switch from one contact to another, and this slider
7
and the conducting pattern
3
a
constitute a rotary electrical part D
1
.
A forcing member
8
consisting of a twisted coil spring has a wound portion
8
a
and a pair of arms
8
b
projecting in the radial direction from the two ends of the wound portion
8
a
. This forcing member
8
is accommodated in the void
6
in a state in which the shaft
4
b
is pressed through the wound portion
8
a
. As shown in
FIG. 6
in particular, it is fitted in a state in which the pair of arms
8
b
are in contact with two of the stubs
4
d
and in contact with two of the engaging stubs
5
k
of the rotor
5
.
Thus, the forcing member
8
intervenes between the rotor
5
and the carrier member
4
.
As in this process the engaging stubs
5
k
are in contact with the arms
8
b
, the rotor
5
is prevented from playing and is in its initial (neutral) position.
When the rotor
5
in this initial position rotates in either the clockwise or counterclockwise direction, the rotor
5
, accompanied by the slider
7
as shown in
FIG. 7
, hooks one of the arms
8
b
and rotates against the elasticity of the arm
8
b
to cause the rotary electrical part D
1
to be operated. At the same time, when the rotor
5
has rotated by a prescribed angle, the stopper
4
f
hits against the walls
5
e
to stop the rotation.
If the rotor
5
in this state is released from rotation, the rotor
5
is returned to its initial position by the elasticity of the arms
8
b
for self-returning.
An operating member
9
is configured of an annular knob
10
and a key top
11
arranged in the central part of this knob
10
, and the knob
10
has an annular base
10
a
, a hole
10
b
bored in the central part of this base
10
a
, a cylinder
10
c
provided to surround this hole
10
b
and protruding downward from the under face of the base
10
a
, a wide notch
10
d
provided in the cylinder
10
c
, engaging portions
10
e
consisting of a plurality of recesses provided in the cylinder
10
c
, a narrow notch
10
f
provided in the cylinder
10
c
, and a convex
10
g
protruding in the radial direction from the outer circumference of the base
10
a.
This knob
10
, in a state in which the flexible insulating substrate
2
and the carrier member
4
are positioned within the cylinder
10
c
, fits the walls
5
e
of the rotor
5
into the cylinder
10
c.
Then, the projections
5
g
of the rotor
5
are snapped onto the engaging portions
10
e
of the cylinder
10
c
, the engaging piece
5
h
is positioned within the notch
10
f
of the knob
10
to couple the knob
10
to the rotor
5
, and at the same time the rotation of the knob
10
causes the rotor
5
to turn.
Thus, with the circular hole
5
b
bearing the shaft
4
b
, the knob
10
and the rotor
5
are enabled to turn.
And the positioning of the engaging piece
5
h
in and its engagement with the notch
10
f
of the knob
10
enables the rotary action of the knob
10
to be reliably transmitted to the rotor
5
.
Although the forcing member
8
intervening between the rotor
5
and the carrier member
4
in the preferred embodiment described above, when the knob
10
is turned, enables the knob
10
to return automatically, the forcing member
8
may as well intervene between the knob
10
and the carrier member
4
to enable the knob
10
to return automatically.
The regulation of the range of rotation of the knob
10
and the rotor
5
is accomplished by the coming into contact of both ends of the cylinder
10
c
positioned on the two sides of notch
10
d
of the knob
10
with the stopper
4
f
of the carrier member
4
.
The key top
11
, which is a molded synthetic resin item, has a saucer-shaped button
11
a consisting of a disk, a collar
11
b
provided on the outer circumference of the button
11
a
, and a suppressor
11
c
consisting of a convex projecting downward from the central part of the under face of the button
11
a.
This key top
11
inserts the button
11
a
into the hole
10
b
of the knob
10
from underneath, and engages the collar
11
b
for the prevention of coming-off with the knob
10
, so that the key top
11
is fitted to the knob
10
to be vertically movable.
A driver
12
, which is a molded synthetic resin item, has a disk-shaped base
12
a
, a suppressor
12
b
projecting downward from the central part of the under face of this base
12
a
, a pair of guide rods
12
c
projecting downward from the outer circumference of the base
12
a
, and a stub
12
d
projecting upward from the periphery of the upper face of the base
12
a.
This driver
12
is arranged between the key top
11
and the plate
4
a
of the carrier member
4
, and is fitted to be vertically movable in a state in which the guide rods
12
c
are inserted into the guide
4
e
of the carrier member
4
and the base
12
a
is in parallel with the plate
4
a
of the carrier member
4
.
Thus, the driver
12
is vertically movable, guided by the guide
4
e.
When the driver
12
is incorporated, the flexible insulating substrate
2
, in a state in which its second link
2
d
is bent toward the driver
12
and the suppressor
12
b
is pressed into the hole
2
m
, the third base
2
e
is positioned on the under face of the base
12
a
of the driver
12
, the third link
2
f
is bent in a U shape to place the second fixed contact
3
c
upward and, in a state in which the stub
12
d
is engaged with the small hole
2
n
, the fourth base
2
g
is mounted over the base
12
a
of the driver
12
.
First and second movable contacts
13
and
14
consist of dome-shaped leaf springs (click springs) differing in operating force from each other. The first movable contact
13
is arranged between the carrier member
4
and the driver
12
in a state in which it is in contact with one (the outer one) of the first fixed contacts
3
b
and is opposite the other (the inner one) of the first fixed contacts
3
b
and the suppressor
12
b
. The second movable contact
14
is arranged between the driver
12
and the key top
11
in a state in which it is in contact with one (the outer one) of the second fixed contacts
3
c
and is opposite the other (the inner one) of the second fixed contacts
3
c
and the suppressor
11
c.
The first movable contact
13
suppresses (comes into contact with) the driver
12
to support the driver
12
, and the second movable contact
14
suppresses (comes into contact with) the key top
11
to support the key top
11
, thereby preventing the driver
12
and the key top
11
from playing.
The first and second movable contacts
13
and
14
are held on the flexible insulating substrate
2
by adhesive tapes.
Between the carrier member
4
and the driver
12
, there is arranged a first push switch part S
1
consisting of the pair of first fixed contacts
3
b
and the first movable contact
13
, and between the key top
11
and the driver
12
, there is arranged a second push switch part S
2
consisting of the pair of second fixed contacts
3
c
and the second movable contact
14
.
These first and second push switch parts S
1
and S
2
are arranged above and underneath the driver
12
with the driver
12
in between. The first and second push switch parts S
1
and S
2
, being arranged in a layered state in the direction of the rotation axis G
1
, are supported over the plate
4
a.
These first and second push switch parts S
1
and S
2
are operated in the following manner. First, when the key top
11
is suppressed, the key top
11
shifts in the direction of the rotation axis G
1
to cause the suppressor
11
c
to suppress the second movable contact
14
, the second movable contact
14
is thereby inverted to click, and the second movable contact
14
comes into contact with the other one (the inner one) of the second fixed contacts
3
c
to work the second push switch part S
2
.
Then, as the key top
11
is further suppressed following the operation described above, the driver
12
shifts in the direction of the rotation axis G
1
to cause the suppressor
12
b
to suppress the first movable contact
13
, the first movable contact
13
is thereby inverted to click, and the first movable contact
13
comes into contact with the other one (the inner one) of the first fixed contacts
3
b
to work the first push switch part S
1
.
The first and second push switch part S
1
and S
2
operating in two stages as described above constitute a double-action push switch unit P
1
.
This double-action push switch unit P
1
, in a state of being positioned toward the key top
11
, arranged on the different side from the rotary electrical part D
1
with the plate
4
a
of the carrier member
4
in between, and the double-action push switch unit P
1
and the rotary electrical part D
1
are arranged in a layered state in the direction of the rotation axis G
1
.
Incidentally, the foregoing description of this embodiment of the invention assumes that the operating force of the first movable contact
13
is greater than that of the second movable contact
14
, but the latter may as well be greater than the former.
Next to describe the operation of the complex operation input device according to the invention, first, as the key top
11
is suppressed in the direction of the rotation axis G
1
, the second movable contact
14
is suppressed by the suppressor
11
c
, the second movable contact
14
is thereby inverted to click, and the second movable contact
14
comes into contact with the other one (the inner one) of the second fixed contacts
3
c
to work the second push switch part S
2
.
Then, as the key top
11
is further suppressed following the operation described above, the driver
12
shifts, while being guided by the guide
4
e
, in the direction of the rotation axis G
1
to cause the suppressor
12
b
to suppress the first movable contact
13
, the first movable contact
13
is thereby inverted to click, and the first movable contact
13
comes into contact with the other one (the inner one) of the first fixed contacts
3
b
to work the first push switch part S
1
.
Then, when the key top
11
is released from suppression, the first movable contact
13
returns to its original state by self-reversal, the driver
12
is pressed back to its original state, the second movable contact
14
also returns to its original state by self-reversal, and the key top
11
is pressed back to its original state, i.e. the state before the suppression.
Next to describe the operation of the rotary electrical part D
1
, in its initial position, the slider
7
is placed over the insulating film
15
, and if in this state the convex
10
g
of the knob
10
is held and the knob
10
is turned from its initial position (neutral position) clockwise or counterclockwise against the forcing member
8
, it is turned until the rotor
5
and the slider
7
are stopped by the stopper
4
f
, with the result that the slider
7
comes into sliding contact with the conducting pattern
3
a
to work the rotary electrical part D
1
.
When the knob
10
is released from rotation, the rotor
5
to which the slider
7
is fitted and the knob
10
are pushed back by the forcing member
8
for self-returning to its initial position.
In this way, the complex operation input device is operated. When used in a digital camera, for instance, such a complex operation input device enables the rotary electrical part D
1
to be suitably used for zooming and the double-action push switch unit P
1
to be suitably used for focusing and shutter releasing.
Although this embodiment of the invention has been described with reference to a configuration in which the operating member
9
is composed of the knob
10
and the key top
11
, another configuration in which only one operating member is used and this single operating member can both rotate and shift in the axial direction is also conceivable.
The first and second push switch parts S
1
and S
2
may either use rubber contacts and the like or be suppressive switches of some other configuration.
Also, the forcing member
8
may consist of some other springy member than a twisted coil spring and, though this embodiment is supposed to use a rotary switch as the rotary electrical part D
1
, it may as well be some other electrical part such as a rotary variable resistor.
FIG. 9
shows a complex operation input device, which is a second preferred embodiment of the present invention. This second embodiment has no forcing member
8
, and also differs from the first embodiment described above in that neither the knob
10
nor the rotor
5
self-returns.
In this second embodiment, a click plate
16
consisting of a metal plate or the like having an uneven surface is fitted to the rotor
5
within the rotor
5
, and a spring
17
to engage with and disengage from this click plate
16
is fitted to the supporting member
1
.
Within the rotor
5
, a detent mechanism
18
consisting of the click plate
16
and the spring
17
is arranged. When the knob
10
is turned clockwise or counterclockwise, the click plate
16
turns together with the rotor
5
, and engages with or disengages from the spring
17
to rotate with articulation, also to work the rotary electrical part D
1
.
Since other aspects of the configuration are the same as the first embodiment of the invention, their description is dispensed with here, the same constituent elements being assigned respectively the same reference numerals.
As the complex operation input device according to the invention has the rotary electrical part D
1
and the double-action push switch unit P
1
manipulated with the operating member
9
arranged in a layered state in the direction of the rotation G
1
of the rotary electrical part D
1
, it can be reduced in size in the lateral direction and can be particularly suitable when used with a portable digital camera or the like.
As the operating member
9
is composed of the rotatable knob
10
and the key top
11
shiftable in the direction of the rotation axis G
1
so that the rotation of the knob
10
cause the rotary electrical part D
1
to be manipulated and the shifting of the key top
11
cause the double-action push switch unit P
1
to be manipulated, the two elements can be manipulated separately, resulting in a complex operation input device capable of reliable operation.
As the key top
11
is positioned in the central part and the annular knob
10
surrounds the outer circumference of the key top
11
, the key top
11
is unlikely to be suppressed inadvertently, resulting in a complex operation input device capable of reliable operation.
Furthermore, as the double-action push switch unit P
1
consists of two, first and second, push switch parts S
1
and S
2
differing from each other in operating force and is supported by the carrier member
4
, with the first and second push switch parts S
1
and S
2
being arranged in a layered state in the direction of the rotation G
1
over the plate
4
a
provided for this carrier member
4
, the first and second push switch parts S
1
and S
2
can accomplish stable suppression and can be reduced in size.
Since the first and second push switch parts S
1
and S
2
are to click by different operating forces, different actions of the double-action push switch unit P
1
can be readily distinguished from each other.
Also, the first and second push switch parts S
1
and S
2
consist of the movable contacts
13
and
14
the fixed contacts
3
b
and
3
c
, respectively, and the movable contacts
13
and
14
are to click, the configuration can be simple and inexpensive.
There also is provided the driver
12
arranged between the key top
11
and the carrier member
4
to be shiftable in the direction of the rotation axis G
1
, and the first and second push switch parts S
1
and S
2
are arranged above and underneath this driver
12
, one above and the other underneath, with the driver
12
in between. As a result, the first and second push switch parts S
1
and S
2
are separated from each other by the driver
12
, and can operate (turning on the contact) more reliably than similar units according to the prior art, which are stacked one over the other.
Of the first and second push switch parts S
1
and S
2
, one is supported over the plate
4
a
, the other is supported over the driver
12
, the suppressive switching unit supported over the plate
4
a
is operated by the driver
12
, and the other supported over the driver
12
is operated by the key top
11
, resulting in more reliable actions of the first and second push switch parts S
1
and S
2
.
As the carrier member
4
(the plate
4
a
) is provided with the guide
4
e
for guiding the shift of the driver
12
in the direction of the rotation axis G
1
, the shift of the driver
12
in the direction of the rotation axis G
1
is made more reliable, resulting in more dependable actions of the first and second push switch parts S
1
and S
2
.
The first and second push switch parts S
1
and S
2
are composed of the single flexible insulating substrate
2
provided with the fixed contacts
3
b
and
3
c
for the first and second push switch parts S
1
and S
2
and the movable contacts
13
and
14
for the first and second push switch parts S
1
and S
2
, coming into and going out of contact with the fixed contacts
3
b
and
3
c
. As the bending of the flexible insulating substrate
2
causes it to be mounted the plate
4
a
or the driver
12
, and the first and second push switch parts S
1
and S
2
are arranged between the key top
11
and the driver
12
and between the driver
12
and the plate
4
a
, respectively, it is required only to dispose the single flexible insulating substrate
2
, resulting in higher productivity and a less expensive product than according to the prior art.
Also, the double-action push switch unit P
1
and the rotary electrical part D
1
are arranged on the different sides of the plate
4
a
of the carrier member
4
and the double-action push switch unit P
1
is positioned toward the key top
11
, resulting in a simple configuration and greater productivity.
The rotary electrical part D
1
is provided with the rotor
5
rotating together with the knob
10
, the slider
7
provided on this rotor
5
, and the conducting pattern
3
a
provided on the flexible insulating substrate
2
and being in sliding contact with the slider
7
, and on the flexible insulating substrate
2
are provided the fixed contacts
3
b
and
3
c
for the first and second push switch parts S
1
and S
2
, with the result that the single flexible insulating substrate
2
can suffice, providing greater productivity and a less expensive product than does the prior art.
Further the supporting member
1
is provided to support the carrier member
4
, and the flexible insulating substrate
2
mounted on the supporting member
1
is held between this supporting member
1
and the carrier member
4
, making it possible to prevent the flexible insulating substrate
2
from floating off and making the actions of the rotary electrical part D
1
more reliable.
Also, the rotor
5
is arranged between the plate
4
a
of the carrier member
4
and the supporting member
1
, and the side walls
5
c
provided on the rotor
5
come into contact with or are positioned close to part of the flexible insulating substrate
2
positioned on the outer circumference of the conducting pattern
3
a
to prevent the flexible insulating substrate
2
from floating off, resulting in further enhanced reliability of the actions of the rotary electrical part D
1
.
Further, the plate
4
a
of the carrier member
4
has the shaft
4
b
provided in its central part and the plurality of projections
4
c
protruding from the end of this shaft
4
b
in the direction of the rotation axis G
1
; the shaft
4
b
is pressed through the hole
5
b
bored in the rotor
5
to support the rotor
5
and the knob
10
rotatably; the projections
4
c
are pressed through the holes
2
k
and
1
a
bored in the flexible insulating substrate
2
and the supporting member
1
, respectively; and the carrier member
4
is fitted to the supporting member
1
by the projections
4
c
, with the result that the fitting of the carrier member
4
is simplified and the flexible insulating substrate
2
can be supported at the same time as the fitting of the carrier member
4
.
As the flexible insulating substrate
2
is held between the end of the shaft
4
b
and the supporting member
1
, the flexible insulating substrate
2
can be supported at the same time as the fitting of the carrier member
4
, resulting in enhanced productivity.
The forcing member
8
intervenes between the carrier member
4
and the rotor
5
and/or the knob
10
, so that when the rotor
5
has rotated via the knob
10
, the rotor
5
is returned to its initial position by the forcing member
8
, with the result that the knob
10
can self-return and manipulating ease is ensured.
Furthermore, as the forcing member
8
is configured of a twisted coil spring, it can be fitted in a state of being held by the shaft
4
b
, resulting in reliable fitting of the forcing member
8
.
Also, as the stopper to limit the range of rotation of the rotor
5
is provided between the carrier member
4
and the rotor
5
, the knob
10
is prevented from rotating more than necessary, and the reliability of operation is thereby ensured.
Moreover, as the rotary electrical part D
1
has the detent mechanism
18
and, when the knob
10
is rotated, the knob
10
is caused to rotate with articulation, the degree of rotation of the knob
10
can be readily perceived to ensure manipulating ease.
Further, as the detent mechanism
18
is arranged within the rotor
5
, the whole device can be built compact.
Claims
- 1. A complex operation input device provided with an operating member, a rotary electrical part manipulated with the operating member a double-action push switch unit manipulated with the operating member, and a driver arranged between the key top and the carrier member and capable of shifting in the direction of the rotation axis,wherein the rotary electrical part and the double-action push switch unit are arranged in a layered state in a direction of a rotation axis of the rotary electrical part, wherein the operating member comprises a rotatable knob and a key top shiftable in the direction of the rotation axis, wherein the rotary electrical part is operated by rotation of the knob and wherein the double-action push switch unit is operated by the shifting of the key top, wherein the double-action push switch unit comprises two, first and second, push switch parts differing from each other in operating force, wherein a carrier member is provided to support the double-action push switch unit, wherein the carrier member has a plate, and wherein over the plate the first and second push switch parts are arranged in a layered state in the direction of the rotation axis, and wherein the first and second push switch parts are arranged above and underneath the driver, one above and the other underneath, with the driver in between.
- 2. The complex operation input device according to claim 1, wherein the knob is annularly shaped and arranged so as to surround an outer circumference of the key top.
- 3. The complex operation input device according to claim 1, wherein the first and second push switch parts click by operating forces differing from each other.
- 4. The complex operation input device according to claim 1, wherein one of the first and second push switch parts is supported over the plate, wherein the other of the first and second push switch parts is supported over the driver, wherein the one suppressive switching unit supported by the plate is operated by the driver, and wherein the other suppressive switching unit supported by the driver is operated by the key top.
- 5. The complex operation input device according to claim 4, wherein the carrier member is provided with a guide for guiding shifting of the driver in the direction of the rotation axis.
- 6. The complex operation input device according to claim 4, wherein the first and the suppressive switching units comprise one flexible insulating substrate provided with fixed contacts for the first and second push switch parts and movable contacts for the first and second push switch parts, to be engaged with and disengaged from the fixed contacts, wherein bending of the flexible insulating substrate causes it to be mounted over the plate or the driver, wherein one of the first and second push switch parts is arranged between the key top and the driver, and wherein the other is arranged between the driver and the plate.
- 7. The complex operation input device according to claim 1, wherein the double-action push switch unit and the rotary electrical part are arranged on different sides of the plate of the carrier member, and wherein the double-action push switch unit is positioned toward the key top.
- 8. The complex operation input device according to claim 7, wherein the rotary electrical part is provided with a rotor rotating together with the knob, a slider provided on the rotor, and a conducting pattern provided on a flexible insulating substrate, the slider coming into sliding contact with the conducting pattern, and wherein fixed contacts for the first and second push switch parts are formed over the flexible insulating substrate.
- 9. The complex operation input device according to claim 8, further provided with a supporting member for supporting the carrier member, wherein the flexible insulating substrate mounted over the supporting member is held between the supporting member and the carrier member.
- 10. The complex operation input device according to claim 9, wherein the rotor is arranged between the plate of the carrier member and the supporting member, wherein side walls provided on the rotor are in contact with or close to part of the flexible insulating substrate positioned on an outer circumference of the conducting pattern to prevent the flexible insulating substrate from floating off.
- 11. The complex operation input device according to claim 9, wherein the plate of the carrier member has a shaft provided in its central part and a plurality of projections protruding from the tip of the shaft in the direction of the rotation axis, wherein the shaft is pressed through a hole bored in the rotor to rotatably support the rotor and the knob, and wherein the projections are pressed through holes bored in the flexible insulating substrate and the supporting member to fit the carrier member to the supporting member.
- 12. The complex operation input device according to claim 11, wherein the flexible insulating substrate is held between the tip of the shaft and the supporting member.
- 13. The complex operation input device according to claim 8, wherein a forcing member intervenes between the carrier member and the rotor and/or the knob and wherein, when the rotor has rotated via the knob, the rotor is returned to its initial position by the forcing member.
- 14. The complex operation input device according to claim 8, wherein a stopper to limit a range of rotation of the rotor is provided between the carrier member and the rotor and/or the knob.
- 15. The complex operation input device according to claim 8, wherein the rotary electrical part has a detent mechanism and wherein, when the knob is rotated, the knob turns with articulation.
- 16. The complex operation input device according to claim 15, wherein the detent mechanism is arranged within the rotor.
Priority Claims (1)
Number |
Date |
Country |
Kind |
2001-143259 |
May 2001 |
JP |
|
US Referenced Citations (7)
Foreign Referenced Citations (1)
Number |
Date |
Country |
10-177826 |
Jun 1998 |
JP |