The present invention relates generally to an operation switch such as a push button switch and the like, and more particularly to improvements in operation switches for decreasing manufacturing and assembly costs by reducing the number of components thereof.
Generally, in a control panel for mechanical equipment such as machine tools and the like, a push-button-type emergency stop switch is provided to emergency-stop mechanical equipment at the time of abnormal circumstances. In such a push-button-type switch, for example, Japanese patent application laying-open publication No. 2003-303527 (hereinafter referred to JP '527) discloses a switch equipped with a “safety-Potentials® structure”, which is a registered trademark of IDEC Corporation, such that contacts of the switch will not return to a contact state in the event that the switch is damaged.
As shown in FIGS. 1 and 2 of JP '527, the button housing 9 receiving the push button 5 includes the compression spring 55 that biases the cylindrical member 45 at the bottom of the push button 5 toward the switch case 3 in the downward direction and the compression spring 31 that is provided at the bottom of the interlocking member 23 coupled to the bottom of the cylindrical member 45 and that biases the interlocking member 23 below the switch case 3 in the downward direction.
In this case, due to resiliently repellent force of the compressive spring 55, the interlocking member 23 is biased downwardly via the cylindrical member 45, and due to resiliently repellent force of the compressive spring 31, the interlocking member 23 is biased downward. Thereby, the movable contact 21 is biased toward the side that the movable contact 21 opens relative to the fixed contact 17.
Through operation of the push button 5, as the movable contact 21 moves away from and opens relative to the fixed contact 17, the amount of deformation of respective compression springs 55, 31 decreases, and elastic energy of respective compression springs 55, 31 thus decreases. That is, elastic energy of respective compression springs 55, 31 after opening of the contacts is smaller than elastic energy of respective compression springs 55, 31 before opening of the contacts.
Therefore, according to the push-button-type switch shown in JP '527, even in the event that the switch is damaged, the contacts will not return to the contact state again thereby displaying “safety-Potentials® function” as a push button switch.
However, in the abovementioned structure of prior art, there needs to be provided a spring discretely from the contacts that biases the movable contact away from the fixed contact, and as a result it is disadvantageous that the number of components increases and thus a manufacturing and assembly cost increases.
The present invention has been made in view of these circumstances and its object is to provide an operation switch that can decrease the number of components to reduce a manufacturing and assembly cost.
An operation switch according to the present invention includes a switch case, an operating member provided at the switch case, and a first contact and a second contact held in the switch case. Through operation of the operating member, the first contact and the second contact are made out of contact. An opening-biasing means is provided in the switch case that biases the first and second contacts in contact away from each other. The opening-biasing means is formed of a leaf spring having the first contact and the second contact.
According to the present invention, since the leaf spring as the opening-biasing means is provided with a first contact and a second contact in the switch case at a portion of the leaf spring, there is no need to provide a spring as the opening-biasing means discretely from the contacts and the leaf spring in itself comes to function as a conductive plate with a contact. Thereby, the number of components of the push button switch can be reduced and a manufacturing and assembly cost can be decreased.
In the operation switch, one of the first contact and the second contact may be a fixed contact secured in the switch case and the other of the first contact and the second contact may be a movable contact fitted at an end of the leaf spring and closable and openable relative to the fixed contact.
In this case, the movable contact at an end of the leaf spring is biased to open relative to the fixed contact due to resiliently repellent force of the leaf spring. Also, in this case, contacts with a single-break structure can be achieved thus decreasing the number of contacts.
In the operation switch, the leaf spring may be provided such that the movable contact is located at a position spaced away and disengaged from the fixed contact when displacement of the leaf spring is zero.
The operation switch may further include a slider in the switch case. The slider may be slidable in conjunction with action of the operating member. The slider may include a first contacting portion that is disposed on one side of the leaf spring and that comes into contact with the leaf spring to cause the movable contact to contact the fixed contact and a second contacting portion that is disposed on the other side of the leaf spring and that comes into contact with the leaf spring to cause the movable contact to open relative to and move away from the fixed contact.
In this case, due to contact of the first contacting portion of the slider with the leaf spring, the movable contact comes into contact with the fixed contact thus maintaining a contact state of the contacts, and also, due to contact of the second contacting portion of the slider with the leaf spring, the movable contact moves away from the fixed contact thus maintaining a non-contact state of the contacts.
In the operation switch, the leaf spring may be composed of a first leaf spring of a general L-shape and a second leaf spring of a general U-shape. The first leaf spring may have a movable contact at one end and a bent portion at an intermediate position between one end and the other end of the first leaf spring. The second leaf spring may have one end coupled to a position opposite the movable contact of the first leaf spring and a bent portion at an intermediate position between one end and the other end of the second leaf spring. A contacting portion may be provided at a position corresponding to the other end of the second leaf spring in the switch case, the contacting portion being adapted to come into contact with the second leaf spring to cause the movable contact to press-contact the fixed contact.
In this case, due to contact of the contacting portion in the switch case with the other end of the second leaf spring, the movable contact of the first leaf spring presses against the fixed contact thus maintaining the contacting state of the contacts. Also, in this case, since the biasing means of the movable contact is composed of two kinds of leaf springs, stress imparted to the spring at the time of displacement of the spring can be dispersed compared with the case that the biasing means is composed of a single leaf spring. In such a way, stress exerted to each of the leaf springs can be mitigated. Moreover, in this case, by properly predetermining rigidity (or rate) of each of the leaf springs, opening timing of the movable contact can be adjusted.
In the operation switch, the first leaf spring and the second leaf spring may be adapted to be located at a position in which the movable contact is open relative to and away from the fixed contact when respective displacements of the first leaf spring and the second leaf spring are zero.
In the operation switch, at least one of the respective bent portions of the first leaf spring and the second leaf spring may be formed of an arc-shaped portion that bulges outwardly from a corner of a general L-shape or a bend of a general U-shape.
In this case, by properly predetermining radius of curvature of the arc-shaped portion, rigidity (or rate) of the first and second leaf springs can be adjusted.
In the operation switch, the respective bent portions of the first leaf spring and the second leaf spring may be each formed of an arc-shaped portion that bulges outwardly from a corner of a general L-shape and a bend of a general U-shape. Radius of curvature of the arc-shaped portion of the first leaf spring may be different from radius of curvature of the arc-shaped portion of the second leaf spring.
For example, in the event that radius of curvature of the arc-shaped portion of the first leaf spring is greater than radius of curvature of the arc-shaped portion of the second leaf spring, bending rigidity of the arc-shaped portion of the first leaf spring is smaller than bending rigidity of the arc-shaped portion of the second leaf spring and the arc-shaped portion of the first leaf spring is thus easier to be bending-deformed than the arc-shaped portion of the second leaf spring. In this case, when the contacting portion in the switch case has come into contact with the other end of the second leaf spring, the first leaf spring is easier to deform than the second leaf spring. Thereby, opening timing of the contacts can be adjusted.
In contrast, in the event that radius of curvature of the arc-shaped portion of the second leaf spring is greater than radius of curvature of the arc-shaped portion of the first leaf spring, bending rigidity of the arc-shaped portion of the second leaf spring is smaller than bending rigidity of the arc-shaped portion of the first leaf spring and the arc-shaped portion of the second leaf spring is thus easier to be bending-deformed than the arc-shaped portion of the first leaf spring. In this case, when the contacting portion in the switch case has come into contact with the other end of the second leaf spring, the second leaf spring is easier to deform than the first leaf spring. Thereby, opening timing of the contacts can be adjusted.
As above-mentioned, according to the operation switch of the present invention, since the first and second contacts are provided in the switch case at a portion of a leaf spring as a contact-opening-biasing means, there is no need to provide a spring as an opening-biasing means discretely from a contact and also the leaf spring in itself comes to function as a conductive plate with a contact. Thereby, the number components can be reduced and a manufacturing and assembly cost can be decreased.
Embodiments of the present invention will be hereinafter described in accordance with the appended drawings.
As shown in
The push button 2 is a cuplike member having a central hole 2a formed therein and annular grooves 2b, 2c formed around the central hole 2a. Between the central hole 2a and the annular grooves 2b, an annular protrusion 2A is formed. The central hole 2a has an engaging projection 2B at a part thereof. The switch case 3 is a cylindrical stepped member with openings at opposite ends thereof. The switch case 3 includes a large cylindrical portion 30 of a larger diameter which is inserted into the annular groove 2c of the push button 2, and a small cylindrical portion 31 of a smaller diameter smaller than the cylindrical portion 30, the cylindrical portion 31 being formed integrally with the cylindrical portion 30. The cylindrical portion 30 has a projection 30a projecting radially inwardly formed therein. On an outer circumferential surface of the cylindrical portion 30, a waterproof packing 35 is fitted in order to prevent water from entering the inside of the push button 2. A part of the outer circumferential surface of the cylindrical portion 31 has an external thread (not shown) formed thereon and a lock nut 36 is screwing engagement with the external thread. A gasket 37 is fitted to a stepped surface of the cylindrical portion 30.
When installing the push button switch 1 to a control panel 10 of a machine tool or the like, first, the cylindrical portion 31 of the switch case 3 is inserted into a mounting through hole 10a formed into the control panel 10, and then the lock nut 36 is screwed onto the cylindrical portion 31 from the inside of the control panel 10 to sandwich the control panel 10 between the lock nut 36 and the gasket 37.
The operating spindle 4 includes a hollow spindle portion 40 extending axially and a flange portion 41 projecting radially outwardly from the spindle portion 40 at a generally central position thereof. An end of the spindle portion 40 is inserted into the central hole 2a of the push button 2. Also, the end of the spindle portion 40 has a radially extending recess 40B formed therein. The engaging projection 2B of the push button 2 is engaged with the recess 40B. The other end of the spindle portion 40 is formed with a radially outwardly projecting projection 40a and a radially inwardly projecting projection 40b. The projection 40a is engaged with the projection 30a of the cylindrical portion 30 of the switch case 3 at an initial position shown in
Inside the cylindrical portion 30 of the switch case 3, a trigger spring 7 is provided. As shown in
The contact unit 5 includes a cylindrical base 50 fixedly attached to the inside of the cylindrical portion 31 of the switch case 3, and a slider 51 slidably supported in the axial direction in the base 50. An end of the slider 51 has an axial portion 52 formed thereon and a distal end of the axial portion 52 is formed with a protrusion 52a protruding radially outwardly. The protrusion 52a is engaged with the projection 40b of the spindle portion 40 of the operating spindle 4 at the initial position shown in
As shown in
As shown in
The movable terminal 55B is formed of a first leaf spring 550 and a second leaf spring 551. The first leaf spring 550 is formed of a relatively thin conductive band-shaped member that is bent into a general L-shape. The first leaf spring 550 has the movable contact 55b at one end and a flexure 550a at a generally central position between the one end and the other end of the first leaf spring 550. The second leaf spring 551 is generally U-shaped. One end of the second leaf spring 551 is coupled to the first leaf spring 550 on the back side of the movable contact 55b of the first leaf spring 550. The second leaf spring 551 has a flexure 551a at a generally central position between the one end and the other end of the second leaf spring 551.
A movable piece 5501 of the first leaf spring 550 that extends linearly toward the inside of the base 50 from the flexure 550a has flexibility (i.e. resilience) in the substantially axial direction. Also, the second leaf spring 551 is formed in such a way that a portion of the first leaf spring 550 is cut out to be deformed into a generally U-shape. The movable piece 5511 of the second leaf spring 551 extending linearly toward the inside of the base 50 from the flexure 551a has flexibility (i.e. resilience) in the substantially axial direction. In addition, the movable contact 56B has a similar structure and its detailed explanation will be omitted. In the initial position where the contacts are contacted with each other as shown in
On the other hand, the slider 51 has a first finger portion 51A and a second finger portion 51B as shown in
In the initial position shown in
As is clearly shown in
Then, operation of the above-mentioned push button switch 1 will be explained in the operational order with reference to
[Initial Position]
At the initial position of the push button switch 1 in which the push button 2 is not pressed, as described in reference to
On this occasion, the movable contact 55b at the distal end of the movable piece 5501 of the first leaf spring 550 is biased to open relative to and move away from the fixed contact 55a due to resilience of the first leaf spring 550. That is, at this juncture, in the state that the first finger portion 51A is not in contact with the movable piece 5511 of the second leaf spring 551 and displacement of the movable piece 5511 is zero, displacement of the movable piece 5501 of the first leaf spring 550 remains zero as well and the movable contact 55b is adapted to be open relative to and spaced away from the fixed contact 55a.
[Preliminary Press Position]
At a preliminary press position in which only the push button 2 is slightly pressed from the state of the initial position, as shown in
Therefore, positional relation between each of the hook portions 71 of the trigger spring 7 and the slope 40c1 of the bulge 40c of the operating spindle 4, displacement of the movable piece 5511 of the second leaf spring 551, displacement of the movable piece 5501 of the first leaf spring 550, and the contact state and pressure between the movable contact 55b and the fixed contact 55a are not changed from the initial position.
[Position Immediately Before Climbing Over Hook Portions]
When the push button 2 is pushed further downwardly from the preliminary press position, the push button switch 1 shifts to the position immediately before the slopes 40c1 climb over hook portions 71 shown in
Also, on this occasion, as the push button 2 is pressed downwardly, the slider 51 is slightly pressed downwardly together with the operating spindle 4 and thus displacement of the movable piece 5511 of the second leaf spring 551 abutting the first finger portion 51A of the slider 51 is decreased. However, in this case as well, the movable piece 5501 of the first leaf spring 550 is displaced due to displacement of the movable piece 5511 of the second leaf spring 551, thereby maintaining the contact state and pressure between the movable contact 55b and the fixed contact 55a.
[Position Immediately after Climbing Over Hook Portions]
When the push button 2 is pushed further downwardly from the position immediately before climbing over hook portions, the push button switch 1 shifts to the position immediately after the slopes 40c1 have climbed over hook portions 71 shown in
Also, on this occasion, as the push button 2 is pressed downwardly, the slider 51 is slightly pressed downwardly together with the operating spindle 4 and thus displacement of the movable piece 5511 of the second leaf spring 551 abutting the first finger portion 51A of the slider 51 is further decreased from the position immediately before the slopes 40c1 of the bulges 40c climbs over the hook portions 71 of the trigger spring 7. However, in this case as well, the movable piece 5501 of the first leaf spring 550 is displaced due to displacement of the movable piece 5511 of the second leaf spring 551, thereby maintaining the contact state and pressure between the movable contact 55b and the fixed contact 55a.
Likewise, in the above-mentioned position immediately after climbing over hook portions from the position immediately before climbing over hook portions, resiliently repellent force of the coil spring 6 which has been compression-deformed as the push button 2 is pressed downwardly acts upon the operating spindle 4. Also, the resiliently restoring force due to deformation of the first leaf spring 550 and the second leaf spring 551 biases the slider 51 downwardly.
[Zero-Displacement Position of Leaf Spring]
The moment when the hook portions 71 of the trigger spring 7 have disengaged from the corresponding slopes 40c1 of the bulges 40c of the operating spindle 4 placed in the position immediately after climbing over hook portions, the operating spindle 4 moves downwardly due to the resiliently repellent force of the coil spring 6, the resiliently restoring force of the first and second leaf springs 550, 551, and auxiliary resiliently repellent force of the coil spring 8. Thereby, the first finger portion 51A of the slider 51 leaves the movable piece 5511 of the second leaf spring 551 and then as shown in
[Lock Position]
When the push button 2 is pushed downwardly from the position immediately before climbing over hook portions shown in
In this lock position, as shown in
In this case, elastic energy stored in the first and second leaf springs 550, 551 by means of elastic deformation of the movable piece 5501 due to contact of the second finger portion 51B of the slider 51 in the lock position is predetermined at a far smaller value than elastic energy that has been stored in the first and second leaf springs 550, 551 by means of elastic deformation of the movable pieces 5501, 5511 due to contact of the first finger portion 51A of the slider 51 in the initial position. Thereby, even in the event that the push button switch 1 is damaged, the contacts can be prevented from returning to the state in contact with each other and thus safety-Potentials® function is maintained.
[Resetting Operation]
When resetting the push button 2 at its original initial position, an operator has only to pull the push button 2 out from the state of the lock position of
Also, as the operating spindle 4 travels, the slider 51 also moves upwardly through the engagement of the projection 40b of the operating spindle 4 with the protrusion 52a of the slider 51.
At this juncture, by the time the push button switch 1 returns to the position of zero displacement of leaf spring, the first leaf spring 550 tries to return to the original position due to its resiliently repellent force and the movable piece 5501 of the first leaf spring 550 is displaced upwardly. Thereafter, due to a press of the first finger portion 51A against the movable piece 5511 of the second leaf spring 551, first, the movable piece 5501 of the first leaf spring 550 with the flexure 550a of an arc-shape of a greater radius of curvature is displaced upwardly. Then, after the movable contact 55b comes into contact with the fixed contact 55a, the movable piece 5511 of the second leaf spring 551 with the flexure 551a of an arc-shape of a smaller radius of curvature is displaced upwardly. In such a manner, the press button switch 1 returns to the initial position.
According to the above-mentioned embodiment, the first leaf spring 550 as a contact-opening-biasing means is provided with the movable contacts 55b or 56b in the switch case 3, there is no need to provide a spring as an opening-biasing means discretely from the contacts and the first spring 550 per se comes to function as a conductive plate with a contact. Thereby, the number of components of the push button switch can be reduced and a manufacturing and assembly cost can be decreased.
Also, in this case, since there is provided the movable contact 55b or 56b at an end of the first leaf spring 550, the contacts can be made a single-break structure thus decreasing the number of contacts.
Moreover, in this case, since the biasing means of the movable contact 55b is formed of two kinds of springs, i.e. the first leaf spring 550 and the second leaf spring 551, a stress exerted to the spring at the time of displacement of the spring can be dispersed compared with the case in which a single leaf spring is used. Thereby, not only each stress imparted to each of the leaf springs can be mitigated but also opening timing of the movable contacts 55b, 56b can be adjusted by properly determining stiffness (or rate) of each of the springs.
Furthermore, since the flexures 550a, 551a of the first and second leaf springs 550, 551 are formed of arc-shaped portions that bulge outwardly from the corner portion of a general L-shape or the bend of a general U-shape, respectively, stiffness of the first and second leaf springs 550, 551 can be adjusted by properly determining radius of curvature of each of the flexures 550a, 551a.
As shown in this embodiment, in the event that radius of curvature of the arc-shaped portion of the first leaf spring 550 is determined at a greater value than radius of curvature of the arc-shaped portion of the second leaf spring 551, bending rigidity of the arc-shaped portion of the first leaf spring 550 becomes smaller than bending rigidity of the arc-shaped portion of the second leaf spring 551 and thus the arc-shaped portion of the first leaf spring 550 becomes easier to bending-deform than the arc-shaped portion of the second leaf spring 551. In this case, when the first finger portion 51A in the switch case 3 comes into contact with the distal end of the movable piece 5511 of the second leaf spring 551, the first leaf spring 550 is easier to deform than the second leaf spring 551 thus adjusting opening timing of the contacts.
To the contrary, in the event that radius of curvature of the arc-shaped portion of the second leaf spring 551 is determined at a greater value than radius of curvature of the arc-shaped portion of the first leaf spring 550, bending rigidity of the arc-shaped portion of the second leaf spring 551 becomes smaller than bending rigidity of the arc-shaped portion of the first leaf spring 550 and thus the arc-shaped portion of the second leaf spring 551 becomes easier to bending-deform than the arc-shaped portion of the first leaf spring 550. In this case, when the first finger portion 51A in the switch case 3 comes into contact with the distal end of the movable piece 5511 of the second leaf spring 551, the second leaf spring 551 is easier to deform than the first leaf spring 550 thus adjusting opening timing of the contacts.
Also, in the above-mentioned embodiment, both of the flexures 550a and 551a of the first and second leaf springs 550, 551 were formed of arc-shaped portions that bulge outwardly, but either one of these flexures 550a, 551a may be formed of an arc-shaped portion.
In this case, a leaf spring with a flexure having an arc-shaped portion is easier to deform thus regulating opening timing of the contacts as with the above-mentioned embodiment.
Additionally, in the above-mentioned embodiment, the movable contact 55b is caused to come into contact with the fixed contact 55a due to contact of the first finger portion 51A with the movable piece 5511 of the second leaf spring 551, which eliminates the necessity for providing a spring for press contact.
As shown in
The fixed terminal 55A′ is formed by bending a relatively thick band-shaped conductive plate in an L-shape and the fixed contact 55a′ is provided at a fixed piece 55A1′ extending in the direction generally perpendicular to the axial direction in the switch case 3′. The movable terminal 55B′ is formed of a leaf spring 550′ composed of a relatively thin band-shaped conductive plate of a general L-shape and has a movable contact 55b′ at one end of the leaf spring 550′ and a flexure 550a′ of a general arc-shape at an intermediate position between the one end and the other end of the leaf spring 550′.
The leaf spring 550′ has a movable piece 5501′ which extends toward the inside of the switch case 3′ from the flexure 550a′ and has resilience in the axial direction. The movable contact 55b′, as shown in a broken line in
There is provided a slider 51′ slidable in the axial direction in the switch case 3′. The slider 51′ is adapted to slide in the switch case 3′ in conjunction with operation of a push button (not shown), similar to the above-mentioned embodiment. The slider 51′ is provided with a first finger portion 51A′ and a second finger portion 51B′. The first finger portion 51A′ is disposed on a lower side of the movable piece 5501′ of the leaf spring 550′ and adapted to come into contact with the movable piece 5501′ to cause the movable contact 55b′ to contact the fixed contact 55a′. The second finger portion 51B′ is disposed on an upper side of the movable piece 5501′ of the leaf spring 550′ and adapted to come into contact with the movable piece 5501′ to cause the movable contact 55b′ to move away from the fixed contact 55a′.
In an initial position shown in
This is not shown in the drawings, but the push button switch 1′ also has a trigger means similar to the trigger spring of the above-mentioned embodiment. The trigger means disengages the axial engagement of an operating spindle in the push button when a stroke of the push button exceeds a certain predetermined extent, and causes the operating spindle to move in the axial direction together with the push button.
Then, operation of the push button switch 1′ will be explained hereinafter.
First, in the initial position of the push button switch 1′ where the push button is not pushed, as explained in reference to
Then, when the push button is pressed, the operating spindle (not shown) in the push button is pressed downwardly. At this moment, the trigger means is activated and thus the first finger portion 51A′ together with the slider 51′ moves downwardly as shown in
By means of operation of the push button, as the slider 51′ travels downwardly, the movable piece 5501′ of the leaf spring 550′ is displaced from the position of
In the position of zero displacement, there is formed a gap between the movable contact 55b′ and the fixed contact 55a′ to cause the contacts to be out of contact. Thereby, the push button switch 1′ is turned off and the machine such as the machine tool has thus emergency-stopped. In the lock position shown in
In this case, elastic energy stored in the leaf spring 550′ in the lock position by means of elastic deformation of the movable piece 5501′ due to contact of the second finger portion 51B′ of the slider 51′ is predetermined at a smaller value than elastic energy that has been stored in the leaf spring 550′ in the initial position by means of elastic deformation of the movable piece 5501′ due to contact of the first finger portion 51A′ of the slider 51′. Thereby, even in the event that the push button switch 1′ is damaged, contacts can be prevented from returning to the contact state thus displaying Safety-Potential® function.
In this case as well, since the leaf spring 550′ as a contact-opening-biasing means is provided with the movable contacts 55b′ in the switch case 3, there is no need to provide a spring as an opening-biasing means discretely from the contacts and the spring 550′ per se comes to function as a conductive plate with a contact. Thereby, the number of components of the push button switch can be reduced and a manufacturing and assembly cost can be decreased.
In each of the embodiments mentioned above, the operating switch according to the present invention was applied to a push-button-type emergency switch, but the application of the present invention is not limited to an emergency switch and the present invention is also applicable to a general normally closed switch in which normally closed contacts are caused to be open due to operation of a push button. Moreover, the present invention also has application to switches such as a selector switch, a cam switch, a safety switch and the like.
As stated above, the present invention is useful for an operation switch such as a push button switch and the like, and suitable especially to a switch that requires decrease in cost by reducing the number of components.
Number | Date | Country | Kind |
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2009-265042 | Nov 2009 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP2010/070250 | 11/8/2010 | WO | 00 | 5/16/2012 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2011/062124 | 5/26/2011 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
5017747 | Nagahara et al. | May 1991 | A |
6096990 | Marin | Aug 2000 | A |
6326572 | Yu | Dec 2001 | B1 |
6717078 | Yoshida et al. | Apr 2004 | B2 |
7081593 | Hopkins | Jul 2006 | B2 |
20040069606 | Lee | Apr 2004 | A1 |
Number | Date | Country |
---|---|---|
51-006662 | Feb 1976 | JP |
59-057817 | Apr 1984 | JP |
2003-303527 | Oct 2003 | JP |
Entry |
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International Search Report of the International Searching Authority for International Application PCT/JP2010/070250, mailed Mar. 1, 2011, 3 pages, Japanese Patent Office. |
English Translation of PCT Written Opinion of the International Searching Authority for International Application PCT/JP2010/070250, mailed Mar. 1, 2011, 6 pages, Japanese Patent Office. |
Number | Date | Country | |
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20120228108 A1 | Sep 2012 | US |