The present invention relates to an electrostatic atomizer and its cleaning method.
Japanese Patent Laid-open Publication No. JP2001-130751 discloses a typical configuration of an automatic coating system including an electrostatic atomizer. Metered feeding of paint to the electrostatic atomizer is effected by a pump, which expels the paint from an external paint source toward the electrostatic atomizer, and a valve, which is housed in a cabinet as a separate member from the paint electrostatic atomizer.
Outline of the automatic coating system is explained with reference to the publication No. JP2001-130751. An electrostatic atomizer is attached to an arm of a robot located on an automatic coating line. The electrostatic atomizer communicates with an external compressed air source and paint tanks of paints of different colors. The valve cabinet houses a number of solenoid valves. Paint in an external paint tank is supplied under pressure by a pump toward the electrostatic atomizer, and metered feeding of paint is substantially controlled by a solenoid valve in the valve cabinet.
When a work is brought to a predetermined position of the automatic coating line, solenoid valves in the valve cabinet are controlled in motion, and a paint passage for a paint of a certain color to coat the work is opened to supply the paint under pressure through the paint passage. Then, the electrostatic atomizer is activated to atomize the paint while receiving supplemental supply of the paint.
Coating robots used in automatic coating lines for vehicles, for example, are commonly used to paint some desired colors. Therefore, every time after a coating robot finishes coating of one vehicle of a certain color, it needs procedures for changing the color to paint the next vehicle of a different color.
Japanese Patent Laid-open Publications No. JP-H08-229446 and No. JP-H11-262696 propose cartridge-type electrostatic atomizers. Publication No. JP-H08-229446 proposes to detachably attach a paint tank unit, having a metered paint feeding means inside, to the electrostatic atomizer. Publication No. JP-H11-262696 proposes to use feed units for respective colors, each having a valve inside, and to removably attach them to the electrostatic atomizer.
The cartridge-type atomizer proposed by the publication No. JP-H08-229446 is explained here. The paint tank unit containing a given quantity of paint is detachably attached to the atomizer, and after completion of a coating process, it is detached to wash the internal paint passage of the atomizer. This cartridge-type electrostatic atomizer has the advantage of shortening the paint passage to be washed upon a change of color, and therefore contributes to saving the quantity of paint washed away from the paint passage.
Problems of the atomizer taught by the publication No. JP-H08-229446 are pointed out here. In this known electrostatic atomizer, a combination of a fluid-driven piston and a cylinder is shown as a metered paint feeding means provided inside the paint tank unit. The paint contained in the cartridge-type paint tank unit is sprayed out of the atomizer by extruding it with the piston in the paint tank unit. However, since combinations of fluid-driven pistons and cylinders, in general, need high mechanical accuracy, here is the problem that the manufacturing cost of the cartridge paint tank unit increases.
If plastic materials are used to form the piston and the cylinder for reduction of the manufacturing cost of the cartridge-type paint tank unit, then the plastic piston and cylinder may absorb and expand with the pain and working fluids, and may change in size. Then, the piston and the cylinder, if made with strict accuracy, will cling to each other and do not work.
In case the piston and the cylinder is made of metals, the electrostatic capacity inevitably increases. Therefore, a relatively thick insulating layer must be provided to prevent leakage of static electricity from the cartridge-type pain tank unit. Here is the problem that the outer dimension of the unit increases.
A common problem involved in systems configured to supply pains from external pain tanks and systems configured to supply paints from cartridge-type paint tank units is that, because the rising characteristics upon starting atomization and the trailing characteristics upon stopping atomization are relatively dull, useless consumption of paints occurs upon starting and stopping atomization.
The electrostatic atomizer is halter during the period from completion of coating of a vehicle (work) to the start of coating of the next work. In this halt period, an amount of the plaint remaining under pressure in the electrostatic atomizer may leak through the paint outlet under the atmospheric presser.
It is therefore an object of the invention to provide an electrostatic atomizer that can reduce the quantity of pain running to waste without contributing to actual coating of works.
A further object of the invention is to provide an electrostatic atomizer that can reduce the quantity of pain that leaks from the atomizer during the halt period of the atomizer.
A still further object of the invention is to provide an electrostatic atomizer including a detachable pain container, which can be simplified in structure of an element to be replaced (corresponding to a conventional cartridge-type paint tank).
A yet further object of the invention is to provide a color changing method for an electrostatic atomizer including a detachable canister, which can reduce the time necessary for color-changing operations including replacement of the canister and cleaning of internal passages.
According to the first aspect of the invention, one of more of those objects can be accomplished basically by an electrostatic atomizer for atomizing electrically charged pain toward a work, comprising:
a paint atomizing means supplied with paint from a paint source and atomizing the paint; and
a paint sucking mechanism located inside the electrostatic atomizer to draw up the paint from the paint source and deliver it to the paint atomizing means.
According to the second aspect of the invention, one of more of those objects can be accomplished by a color-changing method for an electrostatic atomizer having at least two removably attached canisters each housing a paint container containing paint and a cleaning container containing cleaning liquid to draw up the paint from the paint container of selected one of the canisters by means of a paint sucking mechanism provided inside the electrostatic atomizer and to atomize and electrically charge the paint to coat a work, which is a cleaning method of the electrostatic atomizer for cleaning an internal paint path of the electrostatic atomizer during a process of replacing one of the canisters by using the cleaning container of the other canister.
In the electrostatic atomizer according to the invention, since the paint sucking mechanism is provided inside the electrostatic atomizer, the passage for paints between the paint sucking mechanism and the paint atomizing mechanism may be short. Therefore, ON/OFF response of atomization can be improved, and useless atomization upon ON/OFF switching of atomization can be reduced. Thus, useless consumption of paint can be reduced.
The paint sucking mechanism located in the electrostatic atomizer is preferably a pump permitting highly accurate delivery control, such as a gear pump or a mono pump. In this case, controllability of the quantity of paint atomized by the electrostatic atomizer and ON/OFF response of atomization of paint can be enhanced more. When the electrostatic atomizer halts atomization with its gear pump or mono pump being stopped, pressure in the internal pain passages and the paint bags become the atmospheric pressure approximately. Therefore, leakage of the paint from the atomizing means of the electrostatic atomizer can be reduced.
The paint source may be either an external paint tank or a paint tank unit detachably attached to the electrostatic atomizer. The detachable tank unit preferably includes a soft paint bag. The soft paint bag is convenient because it deflates as the paint in the paint bag is sucked by the paint sucking mechanism.
In case a gear pump or a mono pump is used as the paint sucking mechanism, the gear pump or the mono pump is preferably rotatable in the opposite direction upon a change of color to return a residue of paint in the internal paint path of the atomizer back to the paint source and to wash the internal paint path after being cleared of the paint. In this manner, quantity of the paint wasted without being used actually for coating works can be reduced significantly.
The electrostatic atomizer having the detachable paint tank unit preferably includes a cleaning liquid inlet port for introducing cleaning liquid from outside upon cleaning the internal paint path of the electrostatic atomizer before changing the color from one to another, and a cleaning liquid drain port for draining the cleaning liquid used. The cleaning liquid introduced into the electrostatic atomizer is preferably introduced not only into the internal paint path but also into the detachable paint tank unit, such that the cleaning liquid flows into the internal paint path of the electrostatic atomizer through the paint path of the paint tank unit and the connection port between the tank unit paint path and the electrostatic atomizer to wash that portion.
At least two canisters each containing a paint and cleaning liquid can be removably attached to the electrostatic atomizer. In this case, the time required for changing the color with the electrostatic atomizer can be reduced because, when one of the canisters whose paint is used up is replaced by new one, the cleaning liquid in the other canister can be used to clean the connection port between the canister and the internal paint path of the electrostatic atomizer as well as the internal paint path of the electrostatic atomizer.
The electrostatic atomizer according to the present invention is most typically used in connection to an arm of a coating robot. A drive source for driving the paint sucking mechanism is preferably located inside the electrostatic atomizer, but it may be located inside the robot arm. In case the drive source is located inside the robot arm, the electrostatic atomizer can be reduced in weight. In case a servomotor is used as the drive source, it can control the delivery of the paint with high accuracy. When the servomotor as the drive source is located inside the electrostatic atomizer, it is advantageous to enable assembling of the electrostatic atomizer to a conventional coating robot without the need of remodeling the conventional coating robot. The servomotor may be connected to the paint sucking mechanism either directly or via a power transmission means. When the power transmission mechanism is made of an insulating material, a certain insulation distance is assured.
When the servomotor is installed inside the electrostatic atomizer, its location is inherently closer to the paint sucking mechanism. Therefore, quick response to ON/OFF switching of atomization of the paint is assured.
In the method according to the present invention, at least two canisters each containing paint and cleaning liquid are removably attached to the electrostatic atomizer such that, upon exchanging one of the canisters, the other canister can be used to wash the internal paint path of the electrostatic atomizer during the replacement of the former canister. According to this method of the invention, since the interior of the atomizer can be washed during replacement of a canister, the time required for color change including replacement of the canister and cleaning of internal paths of the electrostatic atomizer can be reduced.
The paint tank unit 1 has a hollow pipe 5 extending vertically through the paint bag 2. The hollow pipe 5 has one or more through holes 6 in lower positions of the paint bag 2. The internal space of the paint bag 2 and the internal path of the hollow pipe 5 communicate through the through holes 6. The hollow pipe 5 is a passage permitting the paint in the paint bag 2 to flow out externally and permitting a refill of paint to be introduced into the paint bag 2.
In case of the type configured to introduce a refill of paint from the top end of the hollow pipe 5, the upper end of the hollow pipe 5, i.e. the end surface nearer to the paint bag 2, is preferably configured open while the lower end surface 7 is closed by a film or a sheet, for example. If the hollow pipe 5 is made of a plastic material, the closed end surface 7 may be formed integrally. The closed end surface 7 preferably has an easy-to-cut line 8 extending in the circumferential direction as shown in
More specifically, a refill of paint for refilling the paint bag 2 is introduced from the opening at the upper end or from the lower end of the hollow pipe 5. When the paint is introduced from the upper opening or the lower end of the hollow pipe 5, the paint enters into the paint bag 2, first flowing in the internal path of the hollow pipe 5 and next flowing through the through holes 6. Once the refilling of paint is completed, the opening at the upper end of the hollow pipe 5 is sealed with a cap 10. The cap 10 may be affixed by threading engagement with the upper end of the hollow pipe 5 or may be affixed by tight fitting and/or bonding to the hollow pipe 5.
The electrostatic atomizer 20 including the paint tank unit 1 roughly comprises three segments 22 through 24 that can be separated from each other. The first segment 22 is the atomization generating segment including the bell cup 21 and the air motor (not shown). The atomization generating segment 22 has a central path 25 formed in communication with the bell cup 21. The second segment 23 is a pump segment including a paint suction pump. The third segment 24 is a canister made of, for example, a plastic material and removably accommodating a cartridge-type paint tank unit 1.
Before the paint tank unit 1 is attached to the electrostatic atomizer by, for example, threading engagement of the lower end of the hollow pipe 5, an insertion-purpose hollow needle 30 having a sharp tip for penetrating the lower end of the hollow pipe 5 is attached to the paint tank unit 1 as shown in
The hollow needle 30 is made of a metal or a hard plastic material. In a type where the paint is refilled from the upper end, the closed end surface 7 is cut along the easy-to-cut line 8 (
The pump segment 23 includes a paint feed tube 31 that can be inserted into the central path 25 of the atomization generating segment 22. A paint sucking mechanism is assembled to the paint feed tube 31.
The drive source for rotating the drive shaft 38 may be any of air, liquid and electric drive sources. However, an explosion-proof AC servomotor, which is excellent in response and accurately controllable, is preferable. The drive source is located outside the electrostatic atomizer 20 (typically in a coating robot) or inside the electrostatic atomizer 20. In case the drive source is located inside the electrostatic atomizer 20, the drive source may be connected to the mono pump 35 either directly or via the drive shaft 38.
In case a servomotor is used as the drive source of the mono pump 35, the power transmission means (typically a drive shaft) is preferably made of an insulating material to assure electrical insulation. When the helical shaft 36 inserted into a tube constituting a part of the feed tube 31 rotates, the paint is sucked from the paint bag 2 and supplied to the bell cup 21 via the feed tube 31.
The paint feed tube 31 has an inlet port 31a. Once the paint tank unit 1 is attached to the canister 24, the opening at the lower end of the hollow needle 30 protruding downward from the canister 24 enters into the inlet port 31a of the feed tube 31, for example, and the hollow needle 30 becomes a member constituting a part of the feed tube 31.
A selector valve 39 is provided at the inlet port 31a. By activating the selector valve 39, it is possible to make the first configuration for sucking the paint from the paint bag 2; the second configuration for interrupting communication with the paint source and introducing air from the air source into the feed tube 31; and the third configuration for interrupting communication with the paint source (paint bag 2) and introducing cleaning liquid such as thinner into the feed tube 31. The second and third configurations are used for washing the electrostatic atomizer 20 with cleaning liquid (such as thinner) supplied from outside upon changing the color of paint.
The gear pump 40 as the second example of the paint sucking mechanism has a sucking port 40a projecting upward from the pump segment 23B. The paint sucking port 40a can engage with the lower end of the hollow pipe 5 of the canister 24 or with the hollow needle 30. The paint entering into the paint sucking port 40a is delivered to the central portion of the bell cup 21 under high rotation through the paint feed tube 31 extending downward from the pump segment 23B. The gear pump 40 is driven by the drive shaft 38 explained before.
The gear pump 40 has a shaft-cleaning inlet port and a shaft-cleaning outlet port, 40b and 40c (
The mono pump 35 and the gear pump 50 can accurately control the delivery quantity of paint by control of the revolution thereof as well known in the technical field of pumps. Therefore, by detecting the revolution of the rotary shaft 38 of the mono pump 35 or gear pump 40, the delivery quantity of paint can be controlled accurately.
In case the power source for driving the mono pump 35 or gear pump 40 mounted inside is provided in the electrostatic atomizer 20, the drive shaft 38 for transmitting the power may be short. As a result, the timing of operations of the drive source and the timing of operations of the pump 35 or 40 coincide substantially. Therefore, quick response to ON/OFF switching of atomization is assured.
Once the new paint bag 2 exhausts, the paint tank unit 1 is removed from the canister 24, and a new paint tank unit 1 is attached to the canister 24. In a modified version, the canister 24 may be replaced. The paint tank unit 1 or paint bag 2 may be disposable. However, they are preferably configured reusable by refilling the removed exhausted paint bag with new paint.
To use the paint tank unit 1 repeatedly, a lower cap capable of threading engagement, for example, with the lower end of the hollow pipe 5, for example, and in case the lower cap is made of a plastic material, for example, an easy-to-cut line may be formed in its cap portion. Alternatively, the cap portion of the lower cap may be made of a film or a sheet the hollow needle 30 (
In this manner, when the paint tank unit 1 exhausts, it can be easily recovered usable by removing it and replacing the broken lower cap with a new lower cap. The paint tank unit 1 according to the above-explained embodiment may be configured reusable as well by replacing the hollow pipe 5 having a broken portion in its lower end surface with a new hollow pipe.
It is also possible to wash the interior if the paint bag 2 in the removed paint tank unit 1 and refill it with paint. If only a short period of time as passed after the paint tank unit 1 is removed, it may be refilled with paint without washing the internal cavity thereof. However, if a paint tank unit 1 is reused repeatedly without being washed, sediments will accumulate inside the paint tank unit 1. Therefore, the paint tank unit 1 had better be washed periodically.
The hollow pipe 5 of the paint tank unit 1 has an orifice at the lower end thereof to narrow its inner diameter. In this case, even after a removed exhausted tank unit (paint bag 2) is refilled with paint, the hollow pipe 5 can retain the paint without leakage.
When the color of paint should be changed or the paint in the paint bag 2 is used up, the above-explained first embodiment replaces the paint tank unit 1 including the paint bag 2. However, the second embodiment is configured to replace the canister 24. More specifically, as shown in
The canister 24 includes a check valve of open/shut valve 52 in its paint outlet port 50 or at the lower end of the hollow pipe 5 of the paint tank unit 1 (
In case the paint bag 2 deteriorates due to repetitive use, of paint makes clag in the paint bag 2, it is convenient to permit the paint tank unit 1 (paint bag 2) to be removed from the canister 24 and replaced with new one after removing a canister lid 42 of the canister 24. For example, the lower end of the hollow pipe 5 penetrating the paint bag 2 may be brought into removeable threading engagement with the paint outlet port 50 of the canister 24. In a modified version, the canister 24 may have a structure not including the paint tank unit 1. That is, the canister 24 may be configured as a hard cartridge-type paint container.
In the first and second embodiments explained above, the atomizer has been explained as delivering the paint to a single bell cup 2 from the canister 24. However, as shown in
With reference to the first to third embodiments,
The first to third embodiments have been explained with reference to
Each canister 24A (24B) includes an air-driven three-way selector valve 62. An outlet path 63 of the selector valve 62 is connected to a paint path 65 of the atomizer 20 via a first connection port 64 on the part of the atomizer 20. The paint path 65 of the atomizer 20 is connected to a gear pump 40 for example (which may be a mono pump 35 as well), and the paint in the paint bag 2 is supplied to the bell cup 21 through the gear pump 40 and the paint feed tube 31. By activating the three-way selector valve 62, cleaning liquid (typically, thinner) in the cleaning bag 51 is supplied to the gear pump 40 and the paint feed tube 31 to wash them. The cleaning bags 61 in the first and second canisters 24A, 24B communicate with a bypass cleaning liquid path 68 in the atomizer 20 through the second connection port 67. An air-driven path open/shut valve 69 is interposed in the bypass cleaning liquid path 68.
The atomizer 20 has a branch extension 70 extending laterally straight from near the gear pump 40. The branch extension 70 may be a robot arm alternatively. The branch extension 70 accommodates a cascade 71 for generating a high voltage, an AC servomotor 72, etc., inside. A high voltage generated in the cascade 71 is supplied to the bell cup 21 similarly to conventional devices. The output shaft of the AC servomotor 72 is connected to the gear pump 40 via a drive shaft 38 made of an insulating material. Compressed air, power and control signals to the electrostatic atomizer 20 is supplied through an air hose, signal line, etc. extending in the robot arm 80.
Once the paint bag 2 in the first canister 24A exhausts, the first canister 24A is removed from the electrostatic atomizer 20, and replaced by a new canister containing a paint bag 2 filled with paint. Similarly, once the paint bag 2 in the second canister 24B exhausts, it is replaced by a new canister containing a paint bag 2 filled with paint.
Since the first and second canisters 24A, 24B have their own cleaning bags 61 containing cleaning liquid (typically, thinner or water), the first connection port 64 especially difficult to wash can be reliably cleaned by using the cleaning liquid contained in the cleaning bag 61. More specifically, by activating the three-way selector valve 62, the electrostatic atomizer 20 can take a first mode for drawing paint out of the paint bag 2 of the first or second canister 24A, 24B and delivering it to the bell cup 21 for atomization, and a second mode for interrupting communication with the paint bag 2 and rather making communication with the cleaning bag 61 to supply the cleaning liquid (such as thinner) to the paint path 68 and the gear pump 40 to thereby clean the paint path up to the bell cup 21. In addition, the electrostatic atomizer 20 can wash its paint inlet ports 31a, 20a (
Before taking the second or third mode for changing the color of paint, the gear pump 40 may be rotated reversely to retrieve a residue of paint in the downstream side of the pump 40 back into the paint bag 2. In this manner, quantity of paint discarded in the color-changing process can be reduced.
As a modification, a single canister 40 containing a paint bag 2 and a cleaning bag 61 may be removably attached to the atomizer 20 as shown in
Explained below is a preferred embodiment for cleaning the atomizer 20 using cleaning bags 61 housed in two removable canisters 24A, 24B respectively. When one of the canisters, 24A (or 24B), is replaced for changing the color, the following cleaning method can reduce the time required for the change of color by using the other canister, 24B (or 24A) to clean the atomizer 20.
In
In the fourth embodiment shown in
In the first to fourth embodiments, the pressure around the paint tank (typically a soft paint bag 2) housed in the canister 24 is held in the atmospheric pressure (by, for example, making minute pores in the canister lid 42 shown in
In case a servomotor is used as the drive source of the pump segment 23, excellent response of the servomotor contributes to enhancement of the rising and trailing characteristics of the delivery quantity of paint upon ON/OFF operations. In addition, since the pump segment 23 is located inside the electrostatic atomizer 20 and the length of the paint feed tube 31 downstream the pump segment 23 may be short, the rising and training characteristics of the delivery quantity of paint is improved even more.
Since the paint in the paint bag 2 is sprayed by using the pump segment 23 located inside the electrostatic atomizer 20, the atomizer 20 needs no paint delivery drive mechanism such as a cartridge-type paint tank that was required in conventional techniques. Therefore, the paint tank unit 1 can be simplified in construction, and can be made more inexpensive than conventional cartridge-type paint tanks.
In the first to fourth embodiments explained before with reference to
Even in the electrostatic atomizer 20 supplied with pain from the external paint tank according to the fifth embodiment, the atomized paint is controlled by the pump segment 23 inside the atomizer 20. That is, the paint supplied from the external paint tank is drawn up by the pump segment 23 in the electrostatic atomizer 20, and then dispensed to the bell cup 21 through the paint feed tube 31. Even in the electrostatic atomizer 20 according to the fifth embodiment, The drive source for the pump segment 23 may be located either inside the electrostatic atomizer 20 or in the robot arm 80.
Also in the electrostatic atomizer 20 according to the fifth embodiment, the downstream side (exit side) of the paint path of the pump segment 23 located inside is short. Therefore, the rising and trailing characteristics of the delivery quantity of paint supplied to the bell cup 21 are enhanced. Additionally, when a servomotor is used as the drive source of the pump 23, excellent response of the servomotor significantly enhances the rising and trailing characteristics of the delivery quantity of paint upon ON/OFF operations.
Also in the electrostatic atomizer 20 according to the fifth embodiment, the pump segment 23 may be rotated reversely before a color-changing operation after completion of the preceding coating operation to return the residual paint inside the electrostatic atomizer 20 back to the paint source. In this manner, quantity of paint remaining in the electrostatic atomizer and otherwise discarded in the color-changing process can be reduced.
Heretofore, some embodiments of the invention have been explained. The invention, however, is not limited to these embodiments but contemplates the following modifications, for example.
(1) Although the embodiments have explained as using bell-type electrostatic atomizers, the invention is applicable to gun-type electrostatic atomizers as well, which are configured to atomize paint with the aid of air or hydraulic pressure.
(2) Before starting coating by using a new canister 24, pressurizing air may be supplied to the canister 24 for the purpose of initial supply of paint. This will results in increasing the internal pressure of the canister 23, then compressing the paint bag 2, and extruding a quantity of paint to the pump segment 23. Concerning the initial supply of paint to the pump segment 23, a pair of plates sandwiching the paint bag 2 may be used as a means for applying an external force to the paint bag 2 instead of increasing the internal pressure of the canister 24, and the pair of plates may be moved to reduce their distance.
(3) Before replacing the paint tank unit 1 or canister 24 containing the paint bag 2 after completion of the preceding coating, the mono pump or gear pump is preferably rotated reversely to return the residue of paint in the atomizer 20. In this manner, quantity of paint remaining in the atomizer 20 and discarded after a coating process can be reduced. This is especially effective when the interior of the atomizer is washed with cleaning thinner upon changing the color of paint.
(4) In case a mono pump 35 is used as the pump segment 23, the outlet port 50 of the canister may directly couple with the inlet port 31a of the feed tube 31.
(5) In case a gear pump 40 is used as the pump segment 23; the outlet port 50 of the canister may directly couple with the paint suction port 40a of the gear pump 40.
(6) Instead of the soft paint bag 2, a hard paint container having a port communicating with atmospheric air may be used. Such a hard paint container preferably has an open/shut valve in the atmospheric-air communicating port. The open/shut valve is opened before and after the hard paint container is attached to the electrostatic atomizer 20.
(7) The paint filling the paint bag 2 is not limited to a special kind of paint. It may be either an oil paint or a conductive paint (typically, water paint.)
Number | Date | Country | Kind |
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2003-302281 | Aug 2003 | JP | national |
2003-364394 | Oct 2003 | JP | national |
The present application is a continuation of International Patent Application No. PCT/JP2004/012696, filed Aug. 26, 2004 (incorporated herein by reference), which in turn claims priority from Japanese Patent Application No. JP2003-302281, filed Aug. 27, 2003, and from Japanese Patent Application No. JP2003-364394, filed Oct. 24, 2003.
Number | Name | Date | Kind |
---|---|---|---|
2477004 | Paget | Jul 1949 | A |
3432104 | Kaltenbach | Mar 1969 | A |
4036438 | Soderlind et al. | Jul 1977 | A |
4159081 | Demler et al. | Jun 1979 | A |
4311724 | Scharfenberger | Jan 1982 | A |
4792092 | Elberson et al. | Dec 1988 | A |
4955960 | Behr et al. | Sep 1990 | A |
5080289 | Lunzer | Jan 1992 | A |
5351903 | Mazakas et al. | Oct 1994 | A |
5667144 | Snetting | Sep 1997 | A |
5826805 | Ito et al. | Oct 1998 | A |
6164561 | Yoshida et al. | Dec 2000 | A |
6585481 | Sandkleiva | Jul 2003 | B1 |
6799698 | Ono et al. | Oct 2004 | B2 |
6820824 | Joseph et al. | Nov 2004 | B1 |
20020158148 | Hosoda et al. | Oct 2002 | A1 |
20030234299 | Hosoda et al. | Dec 2003 | A1 |
Number | Date | Country |
---|---|---|
88101597 | Oct 1988 | CN |
0792695 | Aug 2002 | EP |
0967016 | Nov 2004 | EP |
919806 | Feb 1963 | GB |
7-265749 | Oct 1995 | JP |
10-66907 | Mar 1998 | JP |
2000-237648 | Sep 2000 | JP |
2002011396 | Jan 2002 | JP |
2003117447 | Apr 2004 | JP |
Number | Date | Country | |
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20060202067 A1 | Sep 2006 | US |
Number | Date | Country | |
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Parent | PCT/JP2004/012696 | Aug 2004 | US |
Child | 11363490 | US |