Title of Invention	"LINE PRESSURE REGULATING SYSTEM FOR AN AUTOMATIC TRANSMISSION"
Abstract	A line pressure regulating system for an automatic transmission comprises a regulator valve that regulates a line pressure by being provided with a hydraulic pressure from an oil pump, characterized in that regulator valve is controlled such that a resultant force of a variable control pressure and an elastic member makes an equilibrium with a resultant force of the line pressure and a range pressure that is provided in all ranges except the R range.

Title of Invention

"LINE PRESSURE REGULATING SYSTEM FOR AN AUTOMATIC TRANSMISSION"

Abstract

A line pressure regulating system for an automatic transmission comprises a regulator valve that regulates a line pressure by being provided with a hydraulic pressure from an oil pump, characterized in that regulator valve is controlled such that a resultant force of a variable control pressure and an elastic member makes an equilibrium with a resultant force of the line pressure and a range pressure that is provided in all ranges except the R range.

Full Text	LINE PRESSURE REGULATING SYSTEM FOR AN AUTOMATIC TRANSMISSION CROSS-REFERENCE TO RELATED APPLICATION This application claims priority of Korea patent Application No. 10-2000-0082952, filed on December 27, 2000. BACKGROUND OF THE INVENTION (a) Field of the Invention The present invention relates to a regulating system for an automatic transmission, and more particularly, to a line pressure regulating system in which a minimum amount of lubrication oil is provided to the automatic transmission by generating line pressure even in P or N ranges. (b) Description of the Related Art Generally, while an engine is operating, an automatic transmission generates line pressure and provides lubrication oil regardless of a manual valve position. However, because an order of the position of the manual valve range is P, R, N, D, 3, 2 and L, or P, R, N, D, 2 and L, that is, R range is located between the P and N ranges, it is quite difficult to generate a required line pressure in P and N ranges. Thus, there have been line pressure regulating systems in which the line pressure is not generated in the P range. However, in this case, if a vehicle stops for a long time with an engine operating, rotating parts of the transmission are abraded because of lack of lubrication oil. Therefore, a recent automatic transmission generates line pressure even in the P or N ranges so that a minimum amount of lubrication oil is provided to the automatic transmission. As shown in FIG. 1, the aforementioned conventional line pressure regulating system comprises a regulator valve 10 that regulates the line pressure. The regulator valve 10 comprises a valve body 11, a first valve spool 13, a second valve spool 15, an elastic member 17 and plugs 19. The first and second valve spools have different sectional areas. The first valve spool 13 is provided with a first land 21 on which variable control pressure (Pa) regulated by a solenoid valve 40 acts, and a second land 23 on which R range pressure (Pb) transmitted from the manual valve 20 acts, a sectional area of which is larger than that of the first land 21. The first valve spool 13 is installed within the valve body 11 by interposing the plugs 19 between the valve body 11 and the first and second lands respectively. The second valve spool 15 is provided with a first land 25, a second land 27, a third land 29 and a fourth land 31. The second valve spool 15 is elastically supported by the elastic member 17 such that a force of the elastic member acts on the second valve spool 15 in the rightward direction (in the drawing). The first land 25 regulates a torque converter pressure (Pd) by controlling an exit of pressurized oil provided from an oil pump 30. The second land 27 and the third land 29 cooperatively control the line pressure (Pc) by regulating an amount of exhausted oil (EX). The line pressure (Pc) always acts on the fourth land 31. The first, second and third lands of the second valve spool have the same sectional area, and a sectional area of the fourth land is smaller than that of the first, second and third lands. Therefore, in the ranges except the R range, a resultant force of the variable control pressure (Pa) which acts on the first land 21 of the first valve spool 13 and the elastic member 17 makes an equilibrium with a force that is generated by the line pressure (Pc) and acts on the fourth land 31 of the second valve spool 15. The line pressure (Pc) generated in this way provides lubrication oil not only in the D, 3, 2 and L ranges but also in the P and N ranges. In the R range, a resultant force of the variable control pressure (Pa), a force that is generated by the R range pressure (Pb) and acts on the second land 23 of the first valve 13, and a force generated by the elastic member 17 makes an equilibrium with a force generated by the line pressure (Pc). Because the range pressure is generated in the R range, the line pressure (Pc) increases in the R range. However, the aforementioned conventional line pressure regulating system for the automatic transmission has a problem in that if the variable control pressure (Pa) and the line pressure (Pc) acts respectively on the first land 21 of the first valve spool 13 and the fourth land 31 of the second valve spool 15 in opposite directions when an engine starts or the pressure changes rapidly, the first and second valve spools collide with each other and vibrate. Consequently, the line pressure becomes unstable. In addition, because the above conventional line pressure regulating system uses the first valve spool comprising the first and second lands that have different sectional areas and the plugs corresponding to the first valve spool, the system becomes complicated and therefore the cost of production increases. Moreover, because the first and second valve spools and several exhaust ports are needed, length of the system increases, and consequently a degree of freedom of design becomes restricted. SUMMARY OF THE INVENTION The present invention has been made in an effort to solve the above problems. It is an object of the present invention to provide a line pressure regulating system for an automatic transmission in which a generation of line pressure is stable, and a structure of which is simple so that a length of the system can be shortened. The line pressure regulating system of the present invention comprises the regulator valve, in which a resultant force of the variable control pressure and the elastic member makes an equilibrium with a counterpart resultant force of the line pressure and the P, N, D, 3, 2 and L range pressure such that the line pressure can be controlled to be pertinent to each range. BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic view of a conventional line pressure regulating system for an automatic transmission. FIG. 2 is a schematic view of a line pressure regulating system according to the present invention. DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings. FIG. 2 is a schematic view of a line pressure regulating system according to the preferred embodiment of the present invention. As shown in FIG. 2, the line pressure regulating system according to the preferred embodiment comprises a regulator valve 50, being provided with hydraulic pressure from an oil pump 60, that regulates the line pressure to a required level in each range. The oil pump 60 is operated the moment an engine (not shown in the drawing) operates, and it continuously generates hydraulic pressure while the engine operates. The regulator valve 50 comprises a valve body 41, a valve spool 43, a fixed end cap 47 and an elastic member 45 that is interposed between the fixed end cap 47 and the valve spool 43. The fixed end cap 47 can be substituted with an adjustable end cap with an adjusting screw so as to change the force generated by the elastic member 45. The valve spool 43 is provided with a first land 49, a second land 51, a third land 53 and a fourth land 55. A variable control pressure Pg is preferably controlled by a solenoid valve 80. Then, the variable control pressure Pg is introduced into the regulator valve 50. A line pressure Pf is provided by the oil pump 60 such that it is always present while the oil pump operates. The line pressure Pf that is provided between the second land 51 and the third land 53 simultaneously acts on the second land 51 in the leftward direction (in the drawing) and on the third land 53 in the rightward direction (in the drawing). However, the area of the second land 51 is larger than that of the third land 53, and therefore a net force by the line pressure acts in the leftward direction (in the drawing). The regulator valve 50 is designed such that a resultant force of the variable control pressure Pg and the elastic member 45 makes an equilibrium with a resultant force of the line pressure Pf and the range pressure Ph. The variable control pressure Pg and the force generated by the elastic member act on the first land in the rightward direction (in the drawing), and the line pressure Pf and the range pressure Ph respectively act on the second land 51 and the third land 53 in the leftward direction (in the drawing). The range pressure Ph is provided by a manual valve 70, and it is provided in all ranges except the R range. The range pressure Ph is freely determined in accordance with a structure of the manual valve 80. Therefore, the range pressure Ph can be provided by an N range port (not shown in the drawing) and the range pressure Ph can be provided by a D range port (not shown in the drawing) of the manual valve 70. Because the variable control pressure Pg can be controlled to be reduced even when the range pressure Ph is not provided in the P and N ranges, it is also possible that the range pressure Ph is cut off in the P and N ranges and connected in the D, 3, 2 and L ranges. The variable control pressure Pg and the force caused by the elastic member 45 act on the first land 49 in the rightward direction (in the drawing). Contrarily, the line pressure Pf acts on the second land 51 in the leftward direction (in the drawing). The range pressure Ph operates on the third land 53 in the same direction as the line pressure Pf, and in the R range the range pressure is not provided. The fourth land 55 is provided between the first and second lands such that it controls a torque converter control pressure Pj in cooperation with the first land 49, and also controls an exhaust EX of the line pressure ph in cooperation with the second land 51. The first, second and fourth lands have the same sectional areas, and that of the third land is smaller than those of the first, second and fourth lands. The line pressure acting on the second land 51 is provided by the oil pump 60 such that the line pressure Pf is always present while the oil pump operates. A line pressure regulating process using the above stated line pressure regulating system will now be explained. In all ranges except the R range, the resultant force of the variable control pressure Pg and the elastic member 45 respectively acting on the first land 49 makes an equilibrium with the resultant force of the line pressure Pf acting on the second land 51 and the range pressure Ph acting on the third land 53. The line pressure Pf regulated in this way provides lubrication oil not only in D, 3, 2 and L ranges, but also in P and N ranges. In the R range, because the regulator is not provided with the range pressure, the resultant force of the variable control pressure Pg and the elastic member 45 respectively acting on the first land 49 makes an equilibrium with the line pressure Pf acting on the second land 51. Therefore, the line pressure Pf is relatively high in the R range compared with the other ranges. In the preferred embodiment of the present invention, the valve spool 43 is formed unitarily, and therefore a collision between the valve spools doesn't occur, and the structure of the regulator valve 50 also becomes simple. As stated above, the line pressure regulating system for the automatic transmission according to the present invention forms a regulator valve such that the resultant force of the variable control pressure and the elastic member makes an equilibrium with the resultant force of the line pressure and the range pressure. Consequently, the line pressure is stable, the structure is simple and the length of the system is short so that the degree of freedom of design increases. While the present invention has been described in detail with reference to the preferred embodiment, those skilled in the art will appreciate that various modifications and substitutions can be made thereto without departing from the sprit and scope of the present invention as set forth in the appended claims. WE CLAIM: 1. A line pressure regulating system for an automatic transmission comprising a regulator valve that regulates a line pressure in each range by being provided with hydraulic pressure from an oil pump, characterized in that regular valve is controlled such that a resultant force of a variable control pressure and an elastic member makes an equilibrium with a resultant force of a line pressure and a range pressure that is provided in all ranges except an R range. 2. The line pressure regulating system as claimed in claim 1 wherein the variable control pressure is controlled by a solenoid valve. 3. The line pressure regulating system as claimed in claim 1 wherein all range pressures except the R range pressure are provided from a manual valve. 4. The line pressure regulating system as claimed in claim 3 wherein all range pressures except the R range pressure are provided from an N range port of the manual valve. 5. The line pressure regulating system as claimed in claim 3 wherein all the range pressures except the R range pressure are provided from a D range port of the manual valve. 6. The line pressure regulating system as claimed in claim 1 wherein the regulator valve comprises : a valve body; a valve spool on which the variable control pressure, the line pressure and the range pressure act, the valve spool being formed unitarily and being located inside the valve body; and an elastic member that is interposed between the valve body and valve spool such that an elastic force acts on the valve spool. 7. The line pressure regulating system as claimed in claim 6 wherein the valve spool comprises: a first land on which the variable control pressure and an elastic force caused by the elastic member act in a same direction; a second land on which the line pressure acts in an opposite direction o the variable control pressure; a third land on which the range pressure acts in the same direction of the line pressure; and a fourth land that controls a torque converter control pressure in cooperation with the first land, and an exhaust of the line pressure in cooperation with the second land. 8. The line pressure regulating system as claimed in claim 7 wherein the first, second and fourth lands have the same sectional areas and the third land has a smaller sectional area than the first, second and fourth lands such that the line pressure can be increased in the R range. 9. The line pressure regulating system as claimed in claim 7 wherein the line pressure is provided with hydraulic pressure from the oil pump such that the line pressure is always present while the oil pump operates. 10. A line pressure regulating system for an automatic transmission substantially as herein described with reference to the accompanying drawings.

Full Text

LINE PRESSURE REGULATING SYSTEM FOR AN AUTOMATIC
TRANSMISSION
CROSS-REFERENCE TO RELATED APPLICATION
This application claims priority of Korea patent Application No. 10-2000-0082952, filed on December 27, 2000.
BACKGROUND OF THE INVENTION
(a) Field of the Invention
The present invention relates to a regulating system for an automatic transmission, and more particularly, to a line pressure regulating system in which a minimum amount of lubrication oil is provided to the automatic transmission by generating line pressure even in P or N ranges.
(b) Description of the Related Art
Generally, while an engine is operating, an automatic transmission generates line pressure and provides lubrication oil regardless of a manual valve position.
However, because an order of the position of the manual valve range is P, R, N, D, 3, 2 and L, or P, R, N, D, 2 and L, that is, R range is located between the P and N ranges, it is quite difficult to generate a required line pressure in P and N ranges. Thus, there have been line pressure regulating systems in which the line pressure is not generated in the P range. However, in this case, if a vehicle stops for a long time with an engine operating, rotating parts of the transmission are abraded because of lack of lubrication oil.
Therefore, a recent automatic transmission generates line pressure even in the P or N ranges so that a minimum amount of lubrication oil is provided to the automatic transmission.
As shown in FIG. 1, the aforementioned conventional line pressure regulating system comprises a regulator valve 10 that regulates the line pressure. The regulator valve 10 comprises a valve body 11, a first valve spool 13, a second valve spool 15, an elastic member 17 and plugs 19. The first and second valve spools have different sectional areas.
The first valve spool 13 is provided with a first land 21 on which variable control pressure (Pa) regulated by a solenoid valve 40 acts, and a second land 23 on which R range pressure (Pb) transmitted from the manual valve 20 acts, a sectional area of which is larger than that of the first land 21.
The first valve spool 13 is installed within the valve body 11 by interposing the plugs 19 between the valve body 11 and the first and second lands respectively.
The second valve spool 15 is provided with a first land 25, a second land 27, a third land 29 and a fourth land 31. The second valve spool 15 is elastically supported by the elastic member 17 such that a force of the elastic member acts on the second valve spool 15 in the rightward direction (in the drawing).
The first land 25 regulates a torque converter pressure (Pd) by controlling an exit of pressurized oil provided from an oil pump 30. The second land 27 and the third land 29 cooperatively control the line pressure (Pc) by regulating an amount of exhausted oil (EX). The line pressure (Pc) always acts
on the fourth land 31.
The first, second and third lands of the second valve spool have the same sectional area, and a sectional area of the fourth land is smaller than that of the first, second and third lands.
Therefore, in the ranges except the R range, a resultant force of the variable control pressure (Pa) which acts on the first land 21 of the first valve spool 13 and the elastic member 17 makes an equilibrium with a force that is generated by the line pressure (Pc) and acts on the fourth land 31 of the second valve spool 15. The line pressure (Pc) generated in this way provides lubrication oil not only in the D, 3, 2 and L ranges but also in the P and N ranges.
In the R range, a resultant force of the variable control pressure (Pa), a force that is generated by the R range pressure (Pb) and acts on the second land 23 of the first valve 13, and a force generated by the elastic member 17 makes an equilibrium with a force generated by the line pressure (Pc).
Because the range pressure is generated in the R range, the line pressure (Pc) increases in the R range.
However, the aforementioned conventional line pressure regulating system for the automatic transmission has a problem in that if the variable control pressure (Pa) and the line pressure (Pc) acts respectively on the first land 21 of the first valve spool 13 and the fourth land 31 of the second valve spool 15 in opposite directions when an engine starts or the pressure changes rapidly, the first and second valve spools collide with each other and vibrate. Consequently, the line pressure becomes unstable.
In addition, because the above conventional line pressure regulating
system uses the first valve spool comprising the first and second lands that have different sectional areas and the plugs corresponding to the first valve spool, the system becomes complicated and therefore the cost of production increases. Moreover, because the first and second valve spools and several exhaust ports are needed, length of the system increases, and consequently a degree of freedom of design becomes restricted.
SUMMARY OF THE INVENTION
The present invention has been made in an effort to solve the above problems. It is an object of the present invention to provide a line pressure regulating system for an automatic transmission in which a generation of line pressure is stable, and a structure of which is simple so that a length of the system can be shortened.
The line pressure regulating system of the present invention comprises the regulator valve, in which a resultant force of the variable control pressure and the elastic member makes an equilibrium with a counterpart resultant force of the line pressure and the P, N, D, 3, 2 and L range pressure such that the line pressure can be controlled to be pertinent to each range. BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is a schematic view of a conventional line pressure regulating system for an automatic transmission.
FIG. 2 is a schematic view of a line pressure regulating system according to the present invention.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS
Hereinafter, a preferred embodiment of the present invention will be
described in detail with reference to the accompanying drawings.
FIG. 2 is a schematic view of a line pressure regulating system according to the preferred embodiment of the present invention.
As shown in FIG. 2, the line pressure regulating system according to the preferred embodiment comprises a regulator valve 50, being provided with hydraulic pressure from an oil pump 60, that regulates the line pressure to a required level in each range.
The oil pump 60 is operated the moment an engine (not shown in the drawing) operates, and it continuously generates hydraulic pressure while the engine operates.
The regulator valve 50 comprises a valve body 41, a valve spool 43, a fixed end cap 47 and an elastic member 45 that is interposed between the fixed end cap 47 and the valve spool 43. The fixed end cap 47 can be substituted with an adjustable end cap with an adjusting screw so as to change the force generated by the elastic member 45. The valve spool 43 is provided with a first land 49, a second land 51, a third land 53 and a fourth land 55.
A variable control pressure Pg is preferably controlled by a solenoid valve 80. Then, the variable control pressure Pg is introduced into the regulator valve 50.
A line pressure Pf is provided by the oil pump 60 such that it is always present while the oil pump operates.
The line pressure Pf that is provided between the second land 51 and the third land 53 simultaneously acts on the second land 51 in the leftward direction (in the drawing) and on the third land 53 in the rightward direction (in
the drawing). However, the area of the second land 51 is larger than that of the third land 53, and therefore a net force by the line pressure acts in the leftward direction (in the drawing).
The regulator valve 50 is designed such that a resultant force of the variable control pressure Pg and the elastic member 45 makes an equilibrium with a resultant force of the line pressure Pf and the range pressure Ph. The variable control pressure Pg and the force generated by the elastic member act on the first land in the rightward direction (in the drawing), and the line pressure Pf and the range pressure Ph respectively act on the second land 51 and the third land 53 in the leftward direction (in the drawing).
The range pressure Ph is provided by a manual valve 70, and it is provided in all ranges except the R range. The range pressure Ph is freely determined in accordance with a structure of the manual valve 80. Therefore, the range pressure Ph can be provided by an N range port (not shown in the drawing) and the range pressure Ph can be provided by a D range port (not shown in the drawing) of the manual valve 70. Because the variable control pressure Pg can be controlled to be reduced even when the range pressure Ph is not provided in the P and N ranges, it is also possible that the range pressure Ph is cut off in the P and N ranges and connected in the D, 3, 2 and L ranges.
The variable control pressure Pg and the force caused by the elastic member 45 act on the first land 49 in the rightward direction (in the drawing). Contrarily, the line pressure Pf acts on the second land 51 in the leftward direction (in the drawing). The range pressure Ph operates on the third land 53 in the same direction as the line pressure Pf, and in the R range the range
pressure is not provided. The fourth land 55 is provided between the first and second lands such that it controls a torque converter control pressure Pj in cooperation with the first land 49, and also controls an exhaust EX of the line pressure ph in cooperation with the second land 51.
The first, second and fourth lands have the same sectional areas, and that of the third land is smaller than those of the first, second and fourth lands.
The line pressure acting on the second land 51 is provided by the oil pump 60 such that the line pressure Pf is always present while the oil pump operates.
A line pressure regulating process using the above stated line pressure regulating system will now be explained.
In all ranges except the R range, the resultant force of the variable control pressure Pg and the elastic member 45 respectively acting on the first land 49 makes an equilibrium with the resultant force of the line pressure Pf acting on the second land 51 and the range pressure Ph acting on the third land 53. The line pressure Pf regulated in this way provides lubrication oil not only in D, 3, 2 and L ranges, but also in P and N ranges.
In the R range, because the regulator is not provided with the range pressure, the resultant force of the variable control pressure Pg and the elastic member 45 respectively acting on the first land 49 makes an equilibrium with the line pressure Pf acting on the second land 51. Therefore, the line pressure Pf is relatively high in the R range compared with the other ranges.
In the preferred embodiment of the present invention, the valve spool 43 is formed unitarily, and therefore a collision between the valve spools doesn't
occur, and the structure of the regulator valve 50 also becomes simple.
As stated above, the line pressure regulating system for the automatic
transmission according to the present invention forms a regulator valve such
that the resultant force of the variable control pressure and the elastic member
makes an equilibrium with the resultant force of the line pressure and the range
pressure. Consequently, the line pressure is stable, the structure is simple and
the length of the system is short so that the degree of freedom of design
increases.
While the present invention has been described in detail with reference to the preferred embodiment, those skilled in the art will appreciate that various modifications and substitutions can be made thereto without departing from the sprit and scope of the present invention as set forth in the appended claims.

WE CLAIM:
1. A line pressure regulating system for an automatic
transmission comprising a regulator valve that regulates a line pressure in each
range by being provided with hydraulic pressure from an oil pump, characterized
in that
regular valve is controlled such that a resultant force of a variable control pressure and an elastic member makes an equilibrium with a resultant force of a line pressure and a range pressure that is provided in all ranges except an R range.
2. The line pressure regulating system as claimed in claim 1
wherein the variable control pressure is controlled by a solenoid valve.
3. The line pressure regulating system as claimed in claim 1 wherein all range pressures except the R range pressure are provided from a manual valve.
4. The line pressure regulating system as claimed in claim 3 wherein all range pressures except the R range pressure are provided from an N range port of the manual valve.
5. The line pressure regulating system as claimed in claim 3 wherein all the range pressures except the R range pressure are provided from a D range port of the manual valve.
6. The line pressure regulating system as claimed in claim 1 wherein the regulator valve comprises :
a valve body;
a valve spool on which the variable control pressure, the line pressure and the range pressure act, the valve spool being formed unitarily and being located inside the valve body; and

an elastic member that is interposed between the valve body and valve spool such that an elastic force acts on the valve spool.
7. The line pressure regulating system as claimed in claim 6 wherein
the valve spool comprises:
a first land on which the variable control pressure and an elastic force caused by the elastic member act in a same direction;
a second land on which the line pressure acts in an opposite direction o the variable control pressure;
a third land on which the range pressure acts in the same direction of the line pressure; and
a fourth land that controls a torque converter control pressure in cooperation with the first land, and an exhaust of the line pressure in cooperation with the second land.
8. The line pressure regulating system as claimed in claim 7 wherein the first, second and fourth lands have the same sectional areas and the third land has a smaller sectional area than the first, second and fourth lands such that the line pressure can be increased in the R range.
9. The line pressure regulating system as claimed in claim 7 wherein the line pressure is provided with hydraulic pressure from the oil pump such that the line pressure is always present while the oil pump operates.

10. A line pressure regulating system for an automatic transmission substantially as herein described with reference to the accompanying drawings.

Documents:

1160-DEL-2001-Abstract-(08-10-2008).pdf

1160-DEL-2001-Assignment-(08-10-2008).pdf

1160-DEL-2001-Claims-(08-10-2008).pdf

1160-DEL-2001-Claims-(20-11-2009).pdf

1160-del-2001-Correspondence Others-(10-04-2012).pdf

1160-DEL-2001-Correspondence-Others-(08-10-2008).pdf

1160-del-2001-Form-15-(10-04-2012).pdf

1160-del-2001-Petition-137-(10-04-2012).pdf

abstract.pdf

claim.pdf

complete specification.pdf

correspondence-others.pdf

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Patent Number

228552

Indian Patent Application Number

1160/DEL/2001

PG Journal Number

13/2009

Publication Date

27-Mar-2009

Grant Date

05-Feb-2009

Date of Filing

19-Nov-2001

Name of Patentee

HYUNDAI MOTOR COMPANY

Applicant Address

231, YANGJAE-DONG, SEOCHO-KU, SEOUL, KOREA

Inventors:

#	Inventor's Name	Inventor's Address
1	PARK JONG-SOOL	LG VILLAGE 211-303, KEUMGOK-DONG, KWONSUN-KU, SUWON-CITY, KYUNGKI-DO, KOREA
2	LEE CHANG-WOOK LEE	JOOKONG APT. 108-1502, SHINJUNGMAEUL, POONGDUKCHEON-RI, SUJI-EUP, YONGIN-CITY, KYUNGKI-DO, KOREA
3	JANG JAE-DUK	SAN 1-1, MABUK-RI, KOOSUNG-MYEON, YONGIN-CITY, KYUNGKI-DO, KOREA
4	KIM TAE-KYUN	SAN 1-1, MABUK-RI, KOOSUNG-MYEON, YONGIN-CITY, KYUNGKI-DO, KOREA
5	LEE JIN-HEE	SAN 1-1, MABUK-RI, KOOSUNG-MYEON, YONGIN-CITY, KYUNGKI-DO, KOREA
6	SHIM HYUN-SOO	WOOREUK APT. 710-1102, SANBON-DONG, KOONPO-CITY, KYUNGKI-DO, KOREA

PCT International Classification Number

B60K 41/06

PCT International Application Number

N/A

PCT International Filing date

PCT Conventions:

#	PCT Application Number	Date of Convention	Priority Country
1	2000-0082952	2000-12-27	Republic of Korea