Information
-
Patent Grant
-
6479813
-
Patent Number
6,479,813
-
Date Filed
Wednesday, December 27, 200023 years ago
-
Date Issued
Tuesday, November 12, 200221 years ago
-
Inventors
-
Original Assignees
-
Examiners
Agents
-
CPC
-
US Classifications
Field of Search
US
- 250 239
- 250 215
- 396 427
- 396 428
- 396 419
- 348 134
- 348 151
-
International Classifications
-
Abstract
A motor-driven pan-tilt unit such as a pan-tilt camera mount designed to remotely control panning and tilting motion of, for example, a surveillance camera is provided. The pan-tilt unit includes a pan mechanism, a transmitting unit, and an optical signal transmitting unit. The pan mechanism has a stationary housing and a rotary shaft in connection with the camera. The transmitting unit includes a plurality of conductive rings and a plurality of conductive contacts. Each of the conductive rings is mounted on one of the rotary shaft and an inner wall of the stationary housing in electrical contact with one of the conductive contacts to establish transmission of electric power and control signals required for a tilt mechanism and the camera. The optical signal transmitting unit includes a light-emitting element and a light-sensitive element. One of the light-emitting element and the light-sensitive element is attached to an end of the rotary shaft so as to establish transmission of an optical signal from the light-emitting element to the light-sensitive element for transmitting image data from the camera to a signal processing circuit mounted on a stationary part of the pan-tilt unit. The housing defines therewithin a hermetic chamber within which the transmitting unit and the optical signal transmitting unit are disposed, thereby avoiding sticking of dust to the units, for example.
Description
BACKGROUND OF THE INVENTION
1. Technical Field of the Invention
The present invention relates generally to a motor-driven swing unit such as a pan-tilt camera mount designed to remotely control panning and tilting operations of pan and tilt mechanisms for orienting, for example, an image-capturing device such as a surveillance camera vertically and horizontally, and more particularly to an improved structure of a motor-driven swing unit capable of swinging a camera horizontally over a 360° range.
2. Background Art
Japanese Patent First Publication No. 9-284612 discloses an endlessely swingable motor-driven camera mount.
FIG. 6
shows a conventional motor-driven camera mount of such a type. A camera
1
is mounted rotatably on a pan frame
3
through a tilt shaft
2
. The tilt shaft
2
is connected to a tilt motor (not shown) through a gear train (not shown) and works to change a vertical angle of the camera
1
in a tilting operation.
The pan frame
3
is installed on a pan shaft
4
. The pan shaft
4
is rotated by a pan motor (not shown) through a gear train (not shown) and works to change a horizontal angle of the camera
1
in a panning operation.
A bearing housing
5
has disposed therein bearings
6
which support the pan shaft
4
rotatably and is fixed on a fixture frame
7
which fixes the whole of the camera mount on the ceiling. A semitransparent dome cover
8
shields the camera
1
, the tilt shaft
2
, and the pan frame
3
for the purpose of presenting a fine appearance.
The camera mount also includes a slip ring transmitting unit. The slip ring transmitting unit consists of an insulating ring
9
, conductive rings
10
, and conductive contacts
11
. The insulating ring
9
is installed on the periphery of an end portion of the pan shaft
4
projecting from the bearing
6
. The conductive rings
10
are rotated by the pan shaft
4
through the insulating ring
9
. The conductive contacts
11
are installed in a holder
12
secured on the bearing housing
5
through an insulating plate
13
in contact with the conductive rings
10
. The slip ring transmitting unit works to establish transmission of power and control signals between a stationary assembly consisting of the bearing housing
5
and the fixture frame
7
and a swinging assembly consisting of the pan frame
3
and the pan shaft
4
.
The camera mount also includes an optical signal transmitting unit which consists of a light-emitting element
14
and a light-sensitive element
15
. The light-emitting element
14
is disposed within an end of a chamber of the pan shaft
4
. The light-sensitive element
15
is mounted on the holder
12
and faces the light-emitting element
14
. The optical signal transmitting unit converts an optical signal outputted from the light-emitting element
14
representing an image captured by the camera
1
to an electric signal. Specifically, the optical signal transmitting unit works to transmit an image signal from the swinging assembly to the stationary assembly.
The above motor-driven camera mount, however, has the following drawback. The motor-driven camera mount, as described above, has disposed therein the gear trains and stores therein grease for lubrication of the gear trains and elimination of mechanical noises, but oil contained in the grease is evaporated by a rise in inside temperature of the camera mount resulting from running of the pan and tilt motors, which results in formation of rarefied oil mist. The oil mist will stick to the surfaces of the inside parts of the camera mount to form oil films thereon. For example, they are formed on slidable electric contact surfaces of the slip ring transmitting unit and outer surfaces of the light-emitting element
14
and the light-sensitive element
15
of the optical signal transmitting unit The oil films usually absorb dust and lead to a failure of electric contacts between the conductive contacts
11
and the conductive rings
10
of the slip ring transmitting unit and cause the light sensitivity of the light-sensitive element
15
and the amount of light outputted from the light-emitting element
14
to be reduced, thus resulting in a decreased quality of the image signal.
Further, the slip ring transmitting unit is located above the bearing
5
, so that the overall length of the camera mount will be greater than sum of an axial interval between the bearings
5
and a vertical length of the slip ring transmitting unit, thus resulting in an increased size of the camera mount.
SUMMARY OF THE INVENTION
It is therefore a principal object of the invention to avoid the disadvantages of the prior art.
It is another object of the invention to provide a motor-driven swing unit which has a small size, but is capable of keeping the reliability for a long time.
According to one aspect of the invention, there is provided a motor-driven swing unit which comprises: (a) a swing mechanism including a stationary housing and a rotary member disposed within the housing in connection with a device which requires motion control, the swing mechanism swinging the device through the rotary member; (b) a transmitting unit including a plurality of conductive rings and a plurality of conductive contacts, each of the conductive rings being mounted on one of the rotary member and the stationary housing of the swing mechanism in electrical contact with one of the conductive contacts to establish transmission of at least one of required electric power and a required signal therebetween; (c) an optical signal transmitting unit including a light-emitting element and a light-sensitive element separated physically from the light-emitting element, one of the light-emitting element and the light-sensitive element being attached to a portion of the rotary member in optical alignment of the light-emitting element and the light-sensitive element with an axis of rotation of the rotary member so as to establish transmission of an optical signal from the light-emitting element to the light-sensitive element for transmitting data to or from the device; and (d) a hermetic chamber defined within the housing of the swing mechanism, the hermetic chamber having disposed therein the transmitting unit and the optical signal transmitting unit.
In the preferred mode of the invention, a signal processing circuit is further provided which processes an output of the light-sensitive element produced by the optical signal from the light-emitting element. The signal processing circuit includes an AGC amplifier controlling a gain of the output of the light-sensitive element.
The signal processing circuit may also include a frequency compensation circuit for compensating for a frequency of the output of the light-sensitive element.
The hermetic chamber may be filled with inert gas.
The swing mechanism also includes two bearings disposed within the housing at a given interval away from each other in alignment with the axis of rotation of the rotary member for supporting the rotary member rotatably. The hermetic chamber is made up of a first and a second closed chamber. The first closed chamber is formed by a first inner wall of the housing between the two bearings. The second closed chamber is formed by a second inner wall of the housing outside the bearings.
The swing mechanism also includes a cover installed on an open end of the housing to define the second chamber between an inner wall of the cover and a surface of one of the bearings.
BRIEF DESCRIPTION OF THE DRAWINGS
The present invention will be understood more fully from the detailed description given hereinbelow and from the accompanying drawings of the preferred embodiments of the invention, which, however, should not be taken to limit the invention to the specific embodiments but are for the purpose of explanation and understanding only.
In the drawings:
FIG. 1
is a partially vertical sectional view which shows a motor-driven swing unit according to the first embodiment of the invention which is used with a camera mount as an example;
FIG. 2
is a vertical sectional view which shows an internal structure of a signal transmitting unit installed in the swing unit of
FIG. 1
;
FIG. 3
is a circuit diagram which shows an image signal generating circuit and an image signal receiving circuit;
FIG. 4
is a vertical sectional view which shows an internal structure of a signal transmitting unit installed in a motor-driven swing unit according to the second embodiment of the invention;
FIG. 5
is a partially vertical sectional view which shows a display unit with which the signal transmitting unit of
FIG. 4
is used; and
FIG. 6
is a vertical sectional view which shows a conventional motor-driven camera mount.
DESCRIPTION OF THE PREFERRED EMBODIMENTS
Referring to the drawings, wherein like reference numbers refer to like parts in several views, particularly to
FIG. 1
, there is shown a motor-driven swing unit according to the invention. The discussion below will refer to an electrically controlled pan-tilt mount for cameras, but the invention may be used with a swing control unit for any other devices requiring swing motion control.
The motor-driven swing unit includes a signal transmitting unit
20
, a fixture frame
21
, a pan mechanism, and a tilt mechanism, a swing circuit board
26
, a stationary circuit board
27
, and a dome cover
28
.
The signal transmitting unit
20
is installed in the fixture frame
21
and includes the part of the pan mechanism as will be apparent from discussion below. The pan mechanism includes a hollow pan shaft
22
and a pan frame
23
. The fixture frame
21
is secured on the ceiling of a room, for example. The pan shaft
22
is supported to be rotatable relative to the signal transmitting unit
20
. The pan frame
23
is retained by the pan shaft
22
and holds a camera
25
such as a surveillance camera through the tilt shaft
24
. The pan shaft
22
is coupled to and driven by a pan motor (not shown) through a pan gear train (not shown) to swing the pan frame
23
horizontally, thereby changing a horizontal angle of the camera
25
in a panning operation.
The tilt mechanism includes a tilt shaft
24
which is coupled to a tilt motor (not shown) and a tilt gear train (not shown) and works to rotate vertically to change a vertical angle of the camera
25
in a tilting operation. The pan motor, the tilt motor, the pan gear train, and the tilt gear train may have known structures, which are not an essential part of the invention, and explanation thereof in detail will be omitted here
The swing circuit board
26
has mounted thereon a tilt motor drive circuit, a control signal interface circuit, an image signal receiving circuit, and a power supply circuit. The control signal interface circuit establishes transmission of control signals between itself and the swing circuit board
26
. The image signal receiving circuit receives an image signal representing an image captured by the camera
25
.
The dome cover
28
is made of a semitransparent plastic material and covers the camera
25
and the tilt and pan mechanisms for representing a fine appearance of the swing unit and shields orientation of the camera
25
visually.
The signal transmitting unit
20
, as clearly shown in
FIG. 2
, includes a stationary bearing housing
31
as the part of the pan mechanism. The bearing housing
31
has dispose d therein ball bearings
32
a
and
32
b
which retain the pan shaft
22
rotatably for panning the camera
25
and has a flange
31
c
which is, as can be seen in
FIG. 1
, secured on the fixture frame
21
.
The bearing housing
31
, the bearings
32
a
and
32
b
, and the pan shaft
22
define a first closed chamber
33
isolated from the outside of the bearing housing
31
.
Within the first chamber
33
, a slip ring transmitting unit is disposed which includes a plurality of conductive rings
34
, a plurality of conductive contacts
36
, an insulating ring
35
, and an insulating plate
37
. The conductive rings
34
are arranged vertically and mounted on the periphery of the pan shaft
22
between the bearings
32
a
and
32
b
through the insulating ring
35
. The conductive contacts
36
are secured on an inner wall of the bearing housing
31
through the insulating plate
37
so that they are in constant electric contact with the conductive rings
34
, respectively. The conductive contacts
36
are pressed by the insulating plate
37
against the conductive rings
34
elastically to establish constant engagement therewith. The conductive contacts
36
may alternatively be urged elastically using any other additional member.
The conductive rings
34
may alternatively be installed on the inner wall of the bearing housing
31
, while the conductive contacts may be mounted on the pan shaft
22
.
Leads
38
are disposed within the pan shaft
22
to establish electric connections between the conductive rings
34
and the swing circuit board
26
. Additionally, leads
39
extend through a hole formed in the bearing housing
31
to establish electric contacts between the conductive contacts
36
and the stationary circuit board
27
.
The signal transmitting unit
20
also includes a cover
43
which is mounted on an end of the bearing housing
31
to define a second closed chamber
46
together with the bearing
32
a
, an end of the pan shaft
22
, a holder
41
, and a light-emitting element
40
. The second chamber
46
is isolated from the outside of the bearing housing
31
.
Within the second chamber
46
, an optical signal transmitting unit is installed which includes the light-emitting element
40
, a light-sensitive element
42
, and the holder
41
. The light-emitting element
40
is retained by the holder
41
within an end of the pan shaft
22
in alignment of an optical axis thereof with the longitudinal center line (i.e., an axis of rotation) of the pan shaft
22
. The light-sensitive element
42
is installed on an inner wall of the cover
43
in alignment with the light-emitting element
40
and converts light outputted from the light-emitting element
40
into an electrical signal.
Leads
44
extend from the inside of the pan shaft
22
to the swing circuit board
26
to establish electrical connections between the light-emitting element
40
and an image signal generating circuit mounted on the pans circuit board
26
. The image signal generating circuit provides an image signal representing an image captured by the camera
25
to the light-emitting element
40
. The light-emitting element
40
is responsive to the image signal to output an optical signal to the light-sensitive element
42
. The light-sensitive element
42
converts the inputted optical signal into an electrical image signal and outputs it to an image signal receiving circuit mounted on the stationary circuit board
27
through leads
45
.
The power required to actuate the camera
25
, the tilt motor, and each circuit element for the tilt mechanism mounted on the swing circuit board
26
is supplied from the power supply circuit mounted on the stationary circuit board
27
through the leads
39
, the conductive contacts
36
, the conductive rings
34
, and the leads
38
. The electrical communication between each of the conductive contacts
36
and one of the conductive rings
34
is, as described above, kept elastically, thus assuring stable transmission of the power and control signals from the stationary part to the movable port of the swing unit even during rotation of the pan shaft
22
.
The slip ring transmitting unit and the optical signal transmitting unit are, as described above, disposed within the first and second hermetic chambers
33
and
46
, thereby avoiding intrusion of oil mist or dust into the slip ring transmitting unit and the optical signal transmitting unit, which will keep free from oil and dust to the light-emitting element
40
, the light-sensitive element
42
, and the sliding parts of the slip ring transmitting unit, thus ensuring steady transmission of the signals. This also facilitates ease of handling of the slip ring transmitting unit and the optical signal transmitting unit in deassembling processes for the maintenance of the swing unit, thereby minimizing the possibility of breakage of and sticking of dirt to the slip ring transmitting unit and the optical signal transmitting unit.
Between the bearings
32
a
and
32
b
, the slip ring transmitting unit is disposed, thereby allowing the total length of the swing unit to be reduced as compared with the conventional structure shown in FIG.
6
.
FIG. 3
shows circuit structures of the image signal generating circuit and the image signal receiving circuit mounted on the swing circuit board
26
and the stationary circuit board
27
, respectively.
The image signal generating circuit includes a buffer amplifier
50
and a voltage-current converting circuit
51
. The buffer amplifier
50
amplifies an input from the camera
25
and outputs a voltage signal. The voltage-current converting circuit
51
converts the inputted voltage signal into a current signal and outputs it to the light-emitting element
40
made of an LED, for example.
The image signal receiving circuit is connected to the light-sensitive element
42
made of a photo-diode (PD), for example, and includes a current-voltage converting circuit
52
, a buffer amplifier
53
, an f-characteristic compensating circuit
57
, a buffer amplifier
58
, and an AGC amplifier
59
. The current-voltage converting circuit
52
converts a current signal produced by the light-sensitive element
42
into a voltage signal and outputs it to the buffer amplifier
53
. The buffer amplifier
53
amplifies the input and outputs it to the AGC amplifier
59
. The AGC amplifier
59
consists of a gain control amplifier
54
, a signal quantity detecting circuit
55
, and a comparator
56
. The gain control amplifier
59
is responsive to a gain control signal to control the gain. The signal quantity detecting circuit
55
produces an SYNC level signal as a function of the level of an SYNC signal. The comparator
56
compares the SYNC level signal outputted from the signal quantity detecting circuit
55
with a reference level and provides the gain control signal to the gain control amplifier
54
. The f-characteristic compensating circuit
57
compensates for a high frequency component of the output from the gain control amplifier
54
and outputs it to the buffer amplifier
58
. The buffer amplifier
58
amplifies the input from the f-characteristic compensating circuit
57
to produce the image signal.
Operations of the image signal generating circuit and the image signal receiving circuit will be discussed in more detail below.
A signal of an image captured by the camera
25
is first inputted to the buffer amplifier
50
. The buffer amplifier
50
amplifier
53
based on the gain control signal so that the SYNC level signal may be kept at a desired constant level, thereby keeping the level of the image signal constant.
The image signal outputted from the gain control amplifier
54
is inputted to the f-characteristic compensating circuit
57
. The f-characteristic compensating circuit
57
compensates for a reduction in high frequency of the image signal caused by a change in frequency characteristic resulting from the current-to-light conversion of the light-emitting element
40
and a change in frequency characteristic resulting from the light-to-current conversion of the light-sensitive element
42
.
The AGC amplifier
59
, as described above, keeps the level of the SYNC signal constant, thereby keeping the level of the image signal constant regardless of an undesirable change in efficiency of signal transmission in the slip ring transmitting unit and the optical signal transmitting unit caused by the deterioration of the light-emitting element
40
and the light-sensitive element
42
resulting from the use for a long time, a change in ambient temperature, or dirt, thus assuring a high quality of images.
Additionally, the use of the f-characteristic compensating circuit
57
enables compensation for the deterioration in the image signal caused by the frequency dependent characteristics of the light-emitting element
40
and the light-sensitive element
42
, thus assuring a high quality of images.
The bearing housing
31
consists of two parts: a hollow cylindrical member
31
a
and a disc member
31
b
, but may amplifies the input and also subjects it to an impedance-conversion. The current-voltage converting circuit
51
converts the voltage of the input from the buffer amplifier
50
into a current signal required to actuate the light-emitting element
40
optically. The light-emitting element
40
is responsive to the current signal from the voltage-current converting circuit
51
to output an optical signal to the light-sensitive element
42
through the leads
44
.
The light-sensitive element
42
converts the optical signal from the light-emitting element
40
into a current signal and transmits it to the current-voltage converting circuit
52
through the leads
45
. The current-voltage converting circuit
52
converts the input into a voltage signal and outputs it to the gain control amplifier
54
.
The gain control amplifier
54
amplifies the image signal inputted thereinto and outputs it the signal quantity detecting circuit
55
. The signal quantity detecting circuit
55
extracts an SYNC signal from the image signal and produces an SYNC level signal as a function of the level of the SYNC signal. The comparator
56
compares the SYNC signal from the signal quantity detecting circuit
55
with the reference level and produces a gain control signal which works to decrease the gain of the output from the buffer amplifier
53
when the SYNC level signal is greater than the reference level or increase it when the SYNC level signal is smaller than the reference level. The gain control signal is inputted to a gain control signal input terminal of the gain control amplifier
54
. The gain control amplifier
54
adjusts the gain of the output from the buffer alternatively be made of a one-piece member or more than two separate parts.
The ball bearings
32
a
and
32
b
may be replaced with any other type of bearings such as slide bearings using an oil retaining metal.
Either or both of the first and second hermetic chambers
33
and
46
may be filled with inert gas.
FIGS. 4 and 5
show a motor-driven swing unit according to the second embodiment of the invention which is different from the one shown in
FIG. 2
only in that the light-emitting element
40
of the signal transmitting unit
20
is installed on the inner wall of the cover
43
, and the light-sensitive element
42
is retained in the holder
41
fitted within the pan shaft
22
. Other arrangements are identical, and explanation thereof in detail will be omitted here.
FIG. 5
shows an example in which the swing unit of the second embodiment is used with a display unit which visually presents image information to people within a room.
The signal transmitting unit
20
is mounted in a fixture frame
66
. The pan shaft
22
retains a pan frame
63
. The pan frame
63
holds a display
61
through a tilt shaft
62
. The pan shaft
22
is, like the first embodiment, rotated by a pan motor through a gear train to swing the pan frame
63
horizontally, thereby panning the display
61
.
The tilt shaft
62
is, like the first embodiment, rotated by a tilt motor through a gear train to tilt the display
61
vertically.
Unlike the first embodiment, an image signal generating circuit is mounted on a stationary circuit board
64
. An image signal receiving circuit is mounted on a swing circuit board
65
.
In operation, the image signal generating circuit produces an image signal to be indicated on the display
61
visually and outputs it to the light-emitting element
40
. The light-emitting element
40
outputs the image signal optically to the light-sensitive element
42
. The light-sensitive element
42
transmits the image signal to the image signal receiving circuit mounted on the swing circuit board
65
. The signal receiving circuit outputs the image signal to the display
61
.
The power required to actuate the display
61
, the tilt motor, and each circuit element for the tilt mechanism mounted on the swing circuit board
63
and control data for controlling the tilt motor and setting operational conditions of the display
61
are supplied from the stationary circuit board
64
to the swing circuit board
65
through the slip ring transmitting unit. Specifically, the transmission of the power and the control data from a stationary portion to a movable portion of the swing unit through the slip ring transmitting unit enables horizontal endless rotation of the display
61
.
While the present invention has been disclosed in terms of the preferred embodiments in order to facilitate better understanding thereof, it should be appreciated that the invention can be embodied in various ways without departing from the principle of the invention. Therefore, the invention should be understood to include all possible embodiments and modifications to the shown embodiments witch can be embodied without departing from the principle of the invention as set forth in the appended claims. For example, the transmission of the control data through the slip ring transmitting unit may be achieved using the so-called handshake method in which a receiver produces a confirmation signal in response to received data and outputs it to a transmitter, thereby avoiding transmission of erroneous control data resulting from a failure in electrical contact in the slip ring transmitting unit caused by the oxidization of and sticking of dust to the parts of the slip ring transmitting unit. Additionally, a coding circuit and a decoding circuit may be provided in the transmitter and the receiver, respectively. The transmitter may subject the control data to error-correction and outputs it to the receiver, thereby minimizing an error rate of the control data to improve the reliability of the data transmission.
Claims
- 1. A motor-driven swing unit comprising:a swing mechanism including a stationary housing and a rotary member disposed within the housing in connection with a device which requires motion control, said swing mechanism swinging the device through the rotary member; a transmitting unit including a plurality of conductive rings and a plurality of conductive contacts, each of the conductive rings being mounted on one of the rotary member and the stationary housing of said swing mechanism in electrical contact with one of the conductive contacts to establish transmission of at least one of required electric power and a required signal therebetween; an optical signal transmitting unit including a light-emitting element and a light-sensitive element separated physically from the light-emitting element, one of the light-emitting element and the light-sensitive element being attached to a portion of the rotary member in optical alignment of the light-emitting element and the light-sensitive element with an axis of rotation of the rotary member so as to establish transmission of an optical signal from the light-emitting element to the light-sensitive element for transmitting data to or from the device; and a hermetic chamber defined within the housing of said swing mechanism, said hermetic chamber having disposed therein said transmitting unit and said optical signal transmitting unit.
- 2. A motor-driven swing unit as set forth in claim 1, further comprising a signal processing circuit processing an output of the light-sensitive element produced by the optical signal from the light-emitting element, said signal processing circuit including an AGC amplifier controlling a gain of the output of the light-sensitive element.
- 3. A motor-driven swing unit as set forth in claim 1, further comprising a signal processing circuit processing an output of the light-sensitive element produced by the optical signal from the light-emitting element, said signal processing circuit including a frequency compensation circuit for compensating for a frequency of the output of the light-sensitive element.
- 4. A motor-driven swing unit as set forth in claim 1, wherein said hermetic chamber is filled with inert gas.
- 5. A motor-driven swing unit as set forth in claim 1, wherein said swing mechanism also includes two bearings disposed within the housing at a given interval away from each other in alignment with the axis of rotation of the rotary member for supporting the rotary member rotatably, and wherein said hermetic chamber is made up of a first and a second closed chamber, the first closed chamber being formed by a first inner wall of the housing between the two bearings, the second closed chamber being formed by a second inner wall of the housing outside the bearings.
- 6. A motor-driven swing unit as set forth in claim 5, wherein said swing mechanism also includes a cover installed on an open end of the housing to define the second chamber between an inner wall of the cover and a surface of one of the bearings.
Priority Claims (1)
Number |
Date |
Country |
Kind |
11-369877 |
Dec 1999 |
JP |
|
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Kind |
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A |
5760390 |
Vezzalini et al. |
Jun 1998 |
A |
6354749 |
Pfaffenberger, II |
Mar 2002 |
B1 |
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Number |
Date |
Country |
56-128542 |
Oct 1981 |
JP |
9-284612 |
Oct 1997 |
JP |