Title of Invention	A SWITCH SYSTEM FOR AND A METHOD OF DETECTING FAULTS IN AN ELECTRICAL CIRCUIT
Abstract	A switch system for detecting faults in an electrical circuit, comprising: a switch housing (12); a magnet (26) that is mounted inside said switch housing (12) and that generates a magnetic field having magnetic flux; a flux concentration device (28) that is located inside said switch housing (12) and that selectively moves between first and second positions; an actuator assembly (36,28) comprises a pressure detection device (36) coupled to said flux concentration device (28), wherein said actuator assembly is located inside said switch housing, and wherein said pressure detection device receives an input and selects said first and second positions based on said input; and a hall-effect device (30) that is located between said magnet (26) and said flux concentration device (28), that conducts a current having a first value when said magnetic flux is less than a predetermined magnetic flux threshold and that conducts said current having a second current value when said magnetic flux exceeds said predetermined magnetic flux threshold, wherein said first position communicates a first magnetic flux to said hall-effect device (30) and said second position communicates a second magnetic flux that is different from said first magnetic flux to said hall-effect device (30).

Title of Invention

A SWITCH SYSTEM FOR AND A METHOD OF DETECTING FAULTS IN AN ELECTRICAL CIRCUIT

Abstract

A switch system for detecting faults in an electrical circuit, comprising: a switch housing (12); a magnet (26) that is mounted inside said switch housing (12) and that generates a magnetic field having magnetic flux; a flux concentration device (28) that is located inside said switch housing (12) and that selectively moves between first and second positions; an actuator assembly (36,28) comprises a pressure detection device (36) coupled to said flux concentration device (28), wherein said actuator assembly is located inside said switch housing, and wherein said pressure detection device receives an input and selects said first and second positions based on said input; and a hall-effect device (30) that is located between said magnet (26) and said flux concentration device (28), that conducts a current having a first value when said magnetic flux is less than a predetermined magnetic flux threshold and that conducts said current having a second current value when said magnetic flux exceeds said predetermined magnetic flux threshold, wherein said first position communicates a first magnetic flux to said hall-effect device (30) and said second position communicates a second magnetic flux that is different from said first magnetic flux to said hall-effect device (30).

Full Text	FIELD OF THE INVENTION The present invention relates to vehicle diagnostic systems, and more particularly to a switch system for detecting faults in an electrical circuit. BACKGROUND OF THE INVENTION Single throw switches can be used in vehicles to detect the presence of an input, such as fluid pressure. A simple switch includes two metal contacts that selectively connect to conduct current and complete a circuit. Although metal contacts are an acceptable means of conducting current flow, the contacts can form insulating oxides that corrode the metal and prevent the circuit from working properly. Single throw switches operate in two modes, or positions. A first position separates the two contacts to provide an open circuit. A second position connects the contacts to complete the circuit (i.e. close the circuit) and to provide a current path. Accordingly, single throw switches are convenient for switching power to a circuit. However, further applications are limited. SUMMARY OF THE INVENTION Accordingly, the present invention provides a switch for detecting an input. The switch includes a switch housing and a magnet that is mounted inside the switch housing and that generates a magnetic field having magnetic flux. The switch further includes a flux concentration device that is located inside the switch housing and that selectively moves between first and second positions. Furthermore, an actuator assembly is located inside the switch housing that receives an input and that selects the first and second positions based on the input. The switch further includes a hall-effect device that is located between the magnet and the flux concentration device. The hall-effect device conducts a current having a first value when the magnetic flux is less than a predetermined magnetic flux threshold and that conducts the current having a second current value when the magnetic flux exceeds the predetermined magnetic flux threshold. The first position communicates a first magnetic flux to the hall-effect device and the second position communicates a second magnetic flux that is different from the first magnetic flux to the hall-effect device. In other features, the switch further includes a metal plate mounted on the inner base of the switch housing. The switch includes a first terminal that has one end that communicates with one side of the hall-effect device and that has an opposite end that communicates with the metal plate. The switch includes a second terminal that has one end that communicates with a side of the hall-effect device opposite of the first terminal and that has an opposite end that extends through the switch housing and outside the switch. In still other features, the switch of claim 1 further includes an inlet. The switch includes a fluid sealing device fixed to the inlet and a chamber located inside the switch housing that is adapted to hold fluid. The inlet directs the fluid to the chamber. In yet other features, the switch includes a pressure detection device adapted to detect a fluid pressure and a linking rod having one end that is coupled to the pressure detection device and having an opposite end that is coupled to the flux concentration device. In another feature, the pressure detection device is a deformable membrane that receives a fluid and deforms based on a fluid pressure caused by the fluid. The fluid pressure causes deformation of the membrane and moves the flux concentration device toward the hall-effect device. In another feature, the flux concentration device is coupled to the base inside the switch housing using springs. When the fluid is not received, the springs position the flux concentration device a first distance away from the hall-effect device. When the fluid is received, the springs compress and position the flux concentration device a second distance away from the hall-effect device. In still another feature, the second distance is less than the first distance. In yet another feature, the second magnetic flux has a higher strength then the first magnetic flux. In still another feature, the magnetic flux threshold includes an upper magnetic flux value and a lower magnetic flux value. BRIEF DESCRIPTION OF THE ACCOMPANYING DRAWINGS The present invention will become more fully understood from the detailed description and the accompanying drawings, wherein: figures 1A and 1B are cross-sectional functional block diagrams of a hall-effect switch according to the principles of the present invention; and Figure 2 is a flow chart illustrating steps executed by a hall- effect switch coupled with a circuit according to the principles of the present invention. DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The following description of the preferred embodiment is merely exemplary in nature and is in no way intended to limit the invention, its application, or uses. For purposes of clarity, the same reference numbers will be used in the drawings to identify similar elements. Referring now to Figures 1A and 1B, an exemplary hall-effect switch 10 adapted to detect fluid pressure is shown. The hall-effect switch 10 includes an outer housing 12 having a top 14 and a pressure chamber 16 within the housing that holds fluid 18. The top couples to a fluid pressure source (not shown) and functions as an inlet to direct fluid 18 to the pressure chamber 16. A sealing device 20 is attached to the housing 12 and surrounds the top 14 to prevent fluid 18 from escaping the switch 10. A metal plate 21 is disposed on the inner base of the housing. A mounting fixture 22 can be coupled to one side of the switch where it couples to the metal plate 21. When the mounting fixture 22 contacts a ground source (not shown), the metal plate become grounded, thereby providing a ground point inside the switch 10. A switch assembly 24 is located within the housing 12. The switch assembly 24 includes a magnet 26, a flux concentration device 28 and a hall-effect device 30. The magnet 26 is fixed to the metal plate 21 and generates a magnetic field (not shown) having magnetic flux (not shown). Although the magnet is shown to be directly mounted to the metal plate 21, the magnet can be mounted to the base of the housing 12. The flux concentration device is located above the magnet 26 and is coupled to the base of the housing 12 using springs 32. The flux concentration device 28 provides a lower resistance path for the magnetic flux. The strength of the magnetic flux can be adjusted by adjusting the position of the flux concentration device 28. For example, the strength of the magnetic flux increases as the flux concentration device 28 moves closer to the magnet 26. The flux concentration device 28 can include a plate made of ferromagnetic material, or another material capable of amplifying magnetic flux. The hall-effect device 30 is located between the magnet 26 and the flux concentration device 28. One end of the hall-effect device 30 communicates with the metal plate 21 using a first lead 33. The opposite end communicates with a terminal 34 using a second lead 35. The terminal 34 extends through the housing 12 and outside of the switch 10. A voltage potential is created across the hall-effect device 30 and a constant biased current flows therein when the metal plate 21 communicates with a ground source (not shown) and the terminal 34 communicates with a voltage source (not shown). Further, placing the hall-effect device 30 in a magnetic field where magnetic flux is received at approximately 90° to the current flow creates a voltage output that is directly proportional to the strength of the magnetic flux. Accordingly, the hall-effect device 30 can include a magnetic flux threshold. When the magnetic flux is below the threshold, the hall-effect device 30 can output a current having a first value. When the magnetic flux exceeds the threshold, the hall-effect device can output a current having a second value. A deformable membrane 36 is centered in the pressure chamber 16 and above the flux concentration device 28. The sides of the membrane 36 are coupled to the inside walls of the housing 12. The bottom of the membrane 36 is coupled to one end of a linking rod 38. The opposite end of the linking rod 38 is coupled to the flux concentration device 28. The switch 10 operates in first and second modes based on the position of the membrane 36. A first mode (LO) can exist when the pressure chamber 16 contains no fluid 18 and the membrane 36 flexes away from the hall- effect device 30. When the membrane 36 flexes away from the hall-effect device 30, the springs 32 are decompressed, thereby holding the flux concentration device 28 in a first position. When the switch 10 is connected to a circuit while in the first position, the flux concentration device 28 delivers a weak magnetic flux to the hall-effect device 30. As a result, the hall-effect device 30 conducts a current in the range of 2mA-5mA. A second mode can exist when fluid 18 is delivered to the pressure chamber 16. As fluid 18 fills the pressure chamber 16, fluid pressure created by the fluid 18 forces the membrane 36 toward the hall-effect device 30. The. linking rod 38 moves the flux concentrator device 28 toward the hall-effect device 30 and into the second position. The second position places the flux concentration device 28 a short distance away from the hall-effect device 30, thereby delivering a high strength magnetic flux. Accordingly, the hall-effect device 30 conducts a current in the range of 12mA-17mA. Although the hall- effect conducts current in the ranges of 2mA-5mA and 12mA-17mA, it is appreciated that another hall-effect that can conduct different current ranges may be used. By using a hall-effect device to conduct current problems caused by corroding metal contacts are reduced. Furthermore, the ability to conduct two different current strengths allows the switch to be used in a wide variety of applications. Referring now to Figure 2, a flowchart illustrates steps executed by a hall-effect switch that is coupled to a circuit according to the principles of the present invention. In step 200, control determines whether the switch has received fluid. When the switch has received fluid, control proceeds to step 204. Otherwise control proceeds to step 202. In step 202, control retains a flux concentration device 28 in a first position and selects a LO mode. Control conducts a low current in step 206 and control ends. In step 204, control flexes the membrane toward the hall-effect device. In step 208, control moves the flux concentration device to a second position and selects a HIGH mode. Control conducts a high current in step 210 and control ends. Those skilled in the art can now appreciate from the foregoing description that the broad teachings of the present invention can be implemented in a variety of forms. Therefore, while this invention has been described in connection with particular examples thereof, the true scope of the invention should not be so limited since other modifications will become apparent to the skilled practitioner upon a study of the drawings, the specification and the following claims. WE CLAIM: 1. A switch system for detecting faults in an electrical circuit, comprising: a switch housing (12); a magnet (26) that is mounted inside said switch housing (12) and that generates a magnetic field having magnetic flux; a flux concentration device (28) that is located inside said switch housing (12) and that selectively moves between first and second positions; an actuator assembly (36,28) comprises a pressure detection device (36) coupled to said flux concentration device (28), wherein said actuator assembly is located inside said switch housing, and wherein said pressure detection device receives an input and selects said first and second positions based on said input; and a hall-effect device (30) that is located between said magnet (26) and said flux concentration device (28), that conducts a current having a first value when said magnetic flux is less than a predetermined magnetic flux threshold and that conducts said current having a second current value when said magnetic flux exceeds said predetermined magnetic flux threshold, wherein said first position communicates a first magnetic flux to said hall- effect device (30) and said second position communicates a second magnetic flux that is different from said first magnetic flux to said hall-effect device (30). 2. The switch system as claimed in claim 1 comprising: a metal plate (25) mounted on an inner base of said switch (10); a first terminal (33,34) that has one end that communicates with one side of said hall-effect device (30) and that has an opposite end that communicates with said metal plate (21); and a second terminal (34,35) that has one end that communicates with a side of said hall-effect device (30) opposite of said first terminal (33,34) and that has an opposite end that extends through said switch housing (12) and outside said switch (10). 3. The switch system as claimed in claim 1 wherein said switch housing (12) comprises: an inlet (14); a fluid sealing device (20) fixed to said inlet (14); and a chamber (16) located inside said switch housing (20) and that is adapted to hold fluid (18), wherein said inlet (14) directs said fluid (18) to said chamber (16). 4. The switch system as claimed in claim 1 wherein said actuator assembly (36, 28) comprises: a pressure detection device (26) coupled to said flux concentration device (28) using a linking rod (38); and wherein said linking rod (38) has one end that is coupled to said pressure detection device (36) and has an opposite end that is coupled to said flux concentration device (28). 5. The switch system as claimed in claim 1, wherein said pressure detection device (36) is a deformable membrane (36) that receives the fluid (18) and deforms based on a fluid pressure caused by said fluid (18) such that said fluid pressure causes deformation of said membrane (36) and moves said flux concentration device (28) toward said hall-effect device (30). 6. The switch system as claimed in claim 1 wherein said flux concentration device (28) is coupled to a base inside said switch housing (12) using springs (32); wherein, when a fluid (18) is not received, said springs (32) position said flux concentration device (28) a first distance away from said hall-effect device (30), and wherein, when said fluid (18) is received, said springs (32) compress and position said flux concentration device (28) a second distance away from said hall-effect device (30). 7. The switch system as claimed in claim 6 wherein said second distance is less than said first distance. 8. The switch system as claimed in claim 1 wherein said second magnetic flux has a higher strength than said first magnetic flux. 9. The switch system as claimed in claim 1 wherein said magnetic flux threshold comprises an upper magnetic flux value and a lower magnetic flux value. 10. A method of detecting an input, comprising: receiving said input using a pressure detection device; generating a magnetic field having a magnetic flux using a magnetic source and a flux concentration device; selectively moving said flux concentration device between first and second positions based on said input; conducting current having first and second current strengths using a hall- effect device that is located between said magnetic source and said flux concentration device; conducting said first current strength when said magnetic flux is less than a predetermined magnetic flux threshold; and conducting said second current strength when said magnetic flux exceeds said predetermined magnetic flux threshold, wherein said first position communicates a first magnetic flux to said hall- effect device and said second position communicates a second magnetic flux that is different from said first magnetic flux to said hall-effect device. 11. The method as claimed in claim 10, wherein said pressure detection device comprises a deformable membrane. 12. The method as claimed in claim 11, comprising coupling one end of a linking rod to said deformable membrane and coupling an opposite end of said linking rod to said flux concentration device. 13. The method as claimed in claim 11 comprising detecting said fluid pressure using a deformable membrane that receives said fluid and deforms based on a fluid pressure of said fluid such that said fluid pressure causes deformation of said membrane and moves said flux concentration device toward said hall-effect device. 14. The method as claimed in claim 10 wherein said second magnetic flux has a higher strength than said first magnetic flux. 15. The method as claimed in claim 10 wherein said magnetic flux threshold comprises an upper magnetic flux value and a lower magnetic flux value. 16. The method as claimed in claim 1, wherein said flux concentration device communicates a first magnetic flux to said hall-effect device when in said first position and said flux concentration device communicates a second magnetic flux that is different from said first magnetic flux to said hall-effect device when in said second position. ABSTRACT TITLE: A SWITCH SYSTEM FOR AND A METHOD OF DETECTING FAULTS IN AN ELECTRICAL CIRCUIT A switch system for detecting faults in an electrical circuit, comprising: a switch housing (12); a magnet (26) that is mounted inside said switch housing (12) and that generates a magnetic field having magnetic flux; a flux concentration device (28) that is located inside said switch housing (12) and that selectively moves between first and second positions; an actuator assembly (36,28) comprises a pressure detection device (36) coupled to said flux concentration device (28), wherein said actuator assembly is located inside said switch housing, and wherein said pressure detection device receives an input and selects said first and second positions based on said input; and a hall-effect device (30) that is located between said magnet (26) and said flux concentration device (28), that conducts a current having a first value when said magnetic flux is less than a predetermined magnetic flux threshold and that conducts said current having a second current value when said magnetic flux exceeds said predetermined magnetic flux threshold, wherein said first position communicates a first magnetic flux to said hall-effect device (30) and said second position communicates a second magnetic flux that is different from said first magnetic flux to said hall-effect device (30).

Full Text

FIELD OF THE INVENTION The present invention relates to vehicle diagnostic systems, and
more particularly to a switch system for detecting faults in an electrical circuit.
BACKGROUND OF THE INVENTION
Single throw switches can be used in vehicles to detect the
presence of an input, such as fluid pressure. A simple switch includes two metal
contacts that selectively connect to conduct current and complete a circuit.
Although metal contacts are an acceptable means of conducting current flow, the
contacts can form insulating oxides that corrode the metal and prevent the circuit
from working properly.
Single throw switches operate in two modes, or positions. A
first position separates the two contacts to provide an open circuit. A second
position connects the contacts to complete the circuit (i.e. close the circuit) and to
provide a current path. Accordingly, single throw switches are convenient for
switching power to a circuit. However, further applications are limited.
SUMMARY OF THE INVENTION Accordingly, the present invention provides a switch for
detecting an input. The switch includes a switch housing and a magnet that is
mounted inside the switch housing and that generates a magnetic field having

magnetic flux. The switch further includes a flux concentration device that is
located inside the switch housing and that selectively moves between first and
second positions. Furthermore, an actuator assembly is located inside the switch
housing that receives an input and that selects the first and second positions
based on the input. The switch further includes a hall-effect device that is
located between the magnet and the flux concentration device. The hall-effect
device conducts a current having a first value when the magnetic flux is less than
a predetermined magnetic flux threshold and that conducts the current having a
second current value when the magnetic flux exceeds the predetermined
magnetic flux threshold. The first position communicates a first magnetic flux to
the hall-effect device and the second position communicates a second magnetic
flux that is different from the first magnetic flux to the hall-effect device.
In other features, the switch further includes a metal plate
mounted on the inner base of the switch housing. The switch includes a first
terminal that has one end that communicates with one side of the hall-effect
device and that has an opposite end that communicates with the metal plate.
The switch includes a second terminal that has one end that communicates with
a side of the hall-effect device opposite of the first terminal and that has an
opposite end that extends through the switch housing and outside the switch.
In still other features, the switch of claim 1 further includes an
inlet. The switch includes a fluid sealing device fixed to the inlet and a chamber
located inside the switch housing that is adapted to hold fluid. The inlet directs
the fluid to the chamber.

In yet other features, the switch includes a pressure detection
device adapted to detect a fluid pressure and a linking rod having one end that is
coupled to the pressure detection device and having an opposite end that is
coupled to the flux concentration device.
In another feature, the pressure detection device is a
deformable membrane that receives a fluid and deforms based on a fluid
pressure caused by the fluid. The fluid pressure causes deformation of the
membrane and moves the flux concentration device toward the hall-effect device. In another feature, the flux concentration device is coupled to
the base inside the switch housing using springs. When the fluid is not received,
the springs position the flux concentration device a first distance away from the
hall-effect device. When the fluid is received, the springs compress and position
the flux concentration device a second distance away from the hall-effect device.
In still another feature, the second distance is less than the first
distance.
In yet another feature, the second magnetic flux has a higher
strength then the first magnetic flux.
In still another feature, the magnetic flux threshold includes an
upper magnetic flux value and a lower magnetic flux value.
BRIEF DESCRIPTION OF THE ACCOMPANYING DRAWINGS The present invention will become more fully understood
from the detailed description and the accompanying drawings, wherein:

figures 1A and 1B are cross-sectional functional block
diagrams of a hall-effect switch according to the principles of the present
invention; and
Figure 2 is a flow chart illustrating steps executed by a hall-
effect switch coupled with a circuit according to the principles of the present
invention.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The following description of the preferred embodiment is merely
exemplary in nature and is in no way intended to limit the invention, its
application, or uses. For purposes of clarity, the same reference numbers will be
used in the drawings to identify similar elements.
Referring now to Figures 1A and 1B, an exemplary hall-effect
switch 10 adapted to detect fluid pressure is shown. The hall-effect switch 10
includes an outer housing 12 having a top 14 and a pressure chamber 16 within
the housing that holds fluid 18. The top couples to a fluid pressure source (not
shown) and functions as an inlet to direct fluid 18 to the pressure chamber 16. A
sealing device 20 is attached to the housing 12 and surrounds the top 14 to
prevent fluid 18 from escaping the switch 10. A metal plate 21 is disposed on the
inner base of the housing. A mounting fixture 22 can be coupled to one side of
the switch where it couples to the metal plate 21. When the mounting fixture 22
contacts a ground source (not shown), the metal plate become grounded,
thereby providing a ground point inside the switch 10.

A switch assembly 24 is located within the housing 12. The
switch assembly 24 includes a magnet 26, a flux concentration device 28 and a
hall-effect device 30. The magnet 26 is fixed to the metal plate 21 and generates
a magnetic field (not shown) having magnetic flux (not shown). Although the
magnet is shown to be directly mounted to the metal plate 21, the magnet can be
mounted to the base of the housing 12. The flux concentration device is located
above the magnet 26 and is coupled to the base of the housing 12 using springs
32. The flux concentration device 28 provides a lower resistance path for the
magnetic flux. The strength of the magnetic flux can be adjusted by adjusting the
position of the flux concentration device 28. For example, the strength of the
magnetic flux increases as the flux concentration device 28 moves closer to the
magnet 26. The flux concentration device 28 can include a plate made of
ferromagnetic material, or another material capable of amplifying magnetic flux.
The hall-effect device 30 is located between the magnet 26 and
the flux concentration device 28. One end of the hall-effect device 30
communicates with the metal plate 21 using a first lead 33. The opposite end
communicates with a terminal 34 using a second lead 35. The terminal 34
extends through the housing 12 and outside of the switch 10.
A voltage potential is created across the hall-effect device 30
and a constant biased current flows therein when the metal plate 21
communicates with a ground source (not shown) and the terminal 34
communicates with a voltage source (not shown). Further, placing the hall-effect
device 30 in a magnetic field where magnetic flux is received at approximately

90° to the current flow creates a voltage output that is directly proportional to the
strength of the magnetic flux. Accordingly, the hall-effect device 30 can include
a magnetic flux threshold. When the magnetic flux is below the threshold, the
hall-effect device 30 can output a current having a first value. When the
magnetic flux exceeds the threshold, the hall-effect device can output a current
having a second value.
A deformable membrane 36 is centered in the pressure
chamber 16 and above the flux concentration device 28. The sides of the
membrane 36 are coupled to the inside walls of the housing 12. The bottom of
the membrane 36 is coupled to one end of a linking rod 38. The opposite end of
the linking rod 38 is coupled to the flux concentration device 28.
The switch 10 operates in first and second modes based on the
position of the membrane 36. A first mode (LO) can exist when the pressure
chamber 16 contains no fluid 18 and the membrane 36 flexes away from the hall-
effect device 30. When the membrane 36 flexes away from the hall-effect device
30, the springs 32 are decompressed, thereby holding the flux concentration
device 28 in a first position. When the switch 10 is connected to a circuit while in
the first position, the flux concentration device 28 delivers a weak magnetic flux
to the hall-effect device 30. As a result, the hall-effect device 30 conducts a
current in the range of 2mA-5mA.
A second mode can exist when fluid 18 is delivered to the
pressure chamber 16. As fluid 18 fills the pressure chamber 16, fluid pressure
created by the fluid 18 forces the membrane 36 toward the hall-effect device 30.

The. linking rod 38 moves the flux concentrator device 28 toward the hall-effect
device 30 and into the second position. The second position places the flux
concentration device 28 a short distance away from the hall-effect device 30,
thereby delivering a high strength magnetic flux. Accordingly, the hall-effect
device 30 conducts a current in the range of 12mA-17mA. Although the hall-
effect conducts current in the ranges of 2mA-5mA and 12mA-17mA, it is
appreciated that another hall-effect that can conduct different current ranges may
be used.
By using a hall-effect device to conduct current problems
caused by corroding metal contacts are reduced. Furthermore, the ability to
conduct two different current strengths allows the switch to be used in a wide
variety of applications.
Referring now to Figure 2, a flowchart illustrates steps
executed by a hall-effect switch that is coupled to a circuit according to the
principles of the present invention. In step 200, control determines whether the
switch has received fluid. When the switch has received fluid, control proceeds
to step 204. Otherwise control proceeds to step 202. In step 202, control retains
a flux concentration device 28 in a first position and selects a LO mode. Control
conducts a low current in step 206 and control ends.
In step 204, control flexes the membrane toward the hall-effect
device. In step 208, control moves the flux concentration device to a second
position and selects a HIGH mode. Control conducts a high current in step 210
and control ends.

Those skilled in the art can now appreciate from the foregoing
description that the broad teachings of the present invention can be implemented
in a variety of forms. Therefore, while this invention has been described in
connection with particular examples thereof, the true scope of the invention
should not be so limited since other modifications will become apparent to the
skilled practitioner upon a study of the drawings, the specification and the
following claims.

WE CLAIM:
1. A switch system for detecting faults in an electrical circuit, comprising:
a switch housing (12);
a magnet (26) that is mounted inside said switch housing (12) and that
generates a magnetic field having magnetic flux;
a flux concentration device (28) that is located inside said switch housing
(12) and that selectively moves between first and second positions;
an actuator assembly (36,28) comprises a pressure detection device (36)
coupled to said flux concentration device (28), wherein said actuator assembly is
located inside said switch housing, and wherein said pressure detection device
receives an input and selects said first and second positions based on said input;
and
a hall-effect device (30) that is located between said magnet (26) and
said flux concentration device (28), that conducts a current having a first value
when said magnetic flux is less than a predetermined magnetic flux threshold
and that conducts said current having a second current value when said
magnetic flux exceeds said predetermined magnetic flux threshold,

wherein said first position communicates a first magnetic flux to said hall-
effect device (30) and said second position communicates a second magnetic
flux that is different from said first magnetic flux to said hall-effect device (30).
2. The switch system as claimed in claim 1 comprising:
a metal plate (25) mounted on an inner base of said switch (10);
a first terminal (33,34) that has one end that communicates with one side
of said hall-effect device (30) and that has an opposite end that communicates
with said metal plate (21); and
a second terminal (34,35) that has one end that communicates with a side
of said hall-effect device (30) opposite of said first terminal (33,34) and that has
an opposite end that extends through said switch housing (12) and outside said
switch (10).
3. The switch system as claimed in claim 1 wherein said switch housing (12)
comprises:
an inlet (14);
a fluid sealing device (20) fixed to said inlet (14); and

a chamber (16) located inside said switch housing (20) and that is
adapted to hold fluid (18),
wherein said inlet (14) directs said fluid (18) to said chamber (16).
4. The switch system as claimed in claim 1 wherein said actuator assembly
(36, 28) comprises:
a pressure detection device (26) coupled to said flux concentration device
(28) using a linking rod (38); and wherein
said linking rod (38) has one end that is coupled to said pressure
detection device (36) and has an opposite end that is coupled to said flux
concentration device (28).
5. The switch system as claimed in claim 1, wherein said pressure detection
device (36) is a deformable membrane (36) that receives the fluid (18) and
deforms based on a fluid pressure caused by said fluid (18) such that said fluid
pressure causes deformation of said membrane (36) and moves said flux
concentration device (28) toward said hall-effect device (30).

6. The switch system as claimed in claim 1 wherein said flux concentration
device (28) is coupled to a base inside said switch housing (12) using springs
(32);
wherein, when a fluid (18) is not received, said springs (32) position said
flux concentration device (28) a first distance away from said hall-effect device
(30), and
wherein, when said fluid (18) is received, said springs (32) compress and
position said flux concentration device (28) a second distance away from said
hall-effect device (30).
7. The switch system as claimed in claim 6 wherein said second distance is
less than said first distance.
8. The switch system as claimed in claim 1 wherein said second magnetic
flux has a higher strength than said first magnetic flux.
9. The switch system as claimed in claim 1 wherein said magnetic flux
threshold comprises an upper magnetic flux value and a lower magnetic flux
value.

10. A method of detecting an input, comprising:
receiving said input using a pressure detection device;
generating a magnetic field having a magnetic flux using a magnetic
source and a flux concentration device;
selectively moving said flux concentration device between first and second
positions based on said input;
conducting current having first and second current strengths using a hall-
effect device that is located between said magnetic source and said flux
concentration device;
conducting said first current strength when said magnetic flux is less than
a predetermined magnetic flux threshold; and
conducting said second current strength when said magnetic flux exceeds
said predetermined magnetic flux threshold,
wherein said first position communicates a first magnetic flux to said hall-
effect device and said second position communicates a second magnetic flux that
is different from said first magnetic flux to said hall-effect device.

11. The method as claimed in claim 10, wherein said pressure detection
device comprises a deformable membrane.
12. The method as claimed in claim 11, comprising coupling one end of a
linking rod to said deformable membrane and coupling an opposite end of said
linking rod to said flux concentration device.
13. The method as claimed in claim 11 comprising detecting said fluid
pressure using a deformable membrane that receives said fluid and deforms
based on a fluid pressure of said fluid such that said fluid pressure causes
deformation of said membrane and moves said flux concentration device toward
said hall-effect device.
14. The method as claimed in claim 10 wherein said second magnetic flux has
a higher strength than said first magnetic flux.

15. The method as claimed in claim 10 wherein said magnetic flux threshold
comprises an upper magnetic flux value and a lower magnetic flux value.
16. The method as claimed in claim 1, wherein said flux concentration device
communicates a first magnetic flux to said hall-effect device when in said first
position and said flux concentration device communicates a second magnetic
flux that is different from said first magnetic flux to said hall-effect device when
in said second position.

ABSTRACT

TITLE: A SWITCH SYSTEM FOR AND A METHOD OF DETECTING FAULTS IN AN
ELECTRICAL CIRCUIT
A switch system for detecting faults in an electrical circuit, comprising: a switch
housing (12); a magnet (26) that is mounted inside said switch housing (12)
and that generates a magnetic field having magnetic flux; a flux concentration
device (28) that is located inside said switch housing (12) and that selectively
moves between first and second positions; an actuator assembly (36,28)
comprises a pressure detection device (36) coupled to said flux concentration
device (28), wherein said actuator assembly is located inside said switch
housing, and wherein said pressure detection device receives an input and
selects said first and second positions based on said input; and a hall-effect
device (30) that is located between said magnet (26) and said flux concentration
device (28), that conducts a current having a first value when said magnetic flux
is less than a predetermined magnetic flux threshold and that conducts said
current having a second current value when said magnetic flux exceeds said
predetermined magnetic flux threshold, wherein said first position communicates
a first magnetic flux to said hall-effect device (30) and said second position
communicates a second magnetic flux that is different from said first magnetic
flux to said hall-effect device (30).

Documents:

00008-kol-2008-abstract.pdf

00008-kol-2008-claims.pdf

00008-kol-2008-correspondence others.pdf

00008-kol-2008-description complete.pdf

00008-kol-2008-drawings.pdf

00008-kol-2008-form 1.pdf

00008-kol-2008-form 2.pdf

00008-kol-2008-form 3.pdf

00008-kol-2008-form 5.pdf

08-KOL-2008-CORRESPONDENCE OTHERS 1.1.pdf

08-KOL-2008-CORRESPONDENCE OTHERS 1.2.pdf

08-KOL-2008-PRIORITY DOCUMENT.pdf

8-KOL-2008-(02-08-2012)-CORRESPONDENCE.pdf

8-KOL-2008-ABSTRACT.pdf

8-KOL-2008-AMANDED CLAIMS.pdf

8-KOL-2008-ASSIGNMENT.pdf

8-KOL-2008-CANCELLED PAGES.pdf

8-KOL-2008-CORRESPONDENCE-1.2.pdf

8-KOL-2008-CORRESPONDENCE.pdf

8-KOL-2008-DESCRIPTION (COMPLETE).pdf

8-KOL-2008-DRAWINGS.pdf

8-KOL-2008-EXAMINATION REPORT REPLY RECIEVED.pdf

8-KOL-2008-EXAMINATION REPORT.pdf

8-KOL-2008-FORM 1.pdf

8-kol-2008-form 18.pdf

8-KOL-2008-FORM 2.pdf

8-KOL-2008-FORM 26.pdf

8-KOL-2008-FORM 3.pdf

8-KOL-2008-FORM 5.pdf

8-KOL-2008-GRANTED-ABSTRACT.pdf

8-KOL-2008-GRANTED-CLAIMS.pdf

8-KOL-2008-GRANTED-DESCRIPTION (COMPLETE).pdf

8-KOL-2008-GRANTED-DRAWINGS.pdf

8-KOL-2008-GRANTED-FORM 1.pdf

8-KOL-2008-GRANTED-FORM 2.pdf

8-KOL-2008-GRANTED-FORM 3.pdf

8-KOL-2008-GRANTED-FORM 5.pdf

8-KOL-2008-GRANTED-SPECIFICATION-COMPLETE.pdf

8-KOL-2008-OTHERS.pdf

8-KOL-2008-PETITION UNDER RULE 137.pdf

8-KOL-2008-TRANSLATED COPY OF PRIORITY DOCUMENT.pdf

abstract-00008-kol-2008.jpg

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Patent Number

258556

Indian Patent Application Number

8/KOL/2008

PG Journal Number

04/2014

Publication Date

24-Jan-2014

Grant Date

21-Jan-2014

Date of Filing

02-Jan-2008

Name of Patentee

GM GLOBAL TECHNOLOGY OPERATIONS, INC.

Applicant Address

300 GM RENAISSANCE CENTER DETROIT, MICHIGAN

Inventors:

#	Inventor's Name	Inventor's Address
1	JACK P. KOSKI	9145 RAVINEWOOD LANE SOUTH LYON, MICHIGAN 48178

PCT International Classification Number

H01H36/00; H01H35/34

PCT International Application Number

N/A

PCT International Filing date

PCT Conventions:

#	PCT Application Number	Date of Convention	Priority Country
1	11/654,903	2007-01-18	U.S.A.