1. A hall effect system, comprising:
a housing;
an input element coupled to the housing;
a magnetic element coupled to the input element and configured to have a detectable magnetic flux;
a sensing element adjacent to the magnetic element, the sensing element being configured to sense the magnetic flux; and
a processing element coupled to the sensing element and configured to determine a position of the magnetic element relative to the sensing element be determining changes in andor the orientation of the magnetic flux upon movement of the interface element by a user.
2. The system of claim 1 wherein the magnetic element is coupled to the input element and configured to move with the input element as a unit relative to the sensing element.
3. The system of claim 1 wherein the magnetic element is carried by a portion of the input element.
4. The system of claim 1, further comprising an interface element coupled to the input element and configured to be engaged and moved by a user to move the input element and the magnetic element relative to the sensing element.
5. The system of claim 1 wherein the housing has a first portion adjacent to the input element and positioned to protect the magnetic element, and the housing has a second portion that supports the sensing element adjacent to the magnetic element.
6. The system of claim 1 wherein the housing has an aperture and at least a portion of the input element extends through the aperture, and further comprising a cover element coupled to the input element and positioned relative to the housing to cover at least a portion of the aperture.
7. The system of claim 6 wherein the cover is connected to the input element and is positioned to engage the housing to restrict the input element and the magnetic element from moving in a direction axially aligned with the input element.
8. The system of claim 1 further comprising a stop element coupled to the input element and the housing to restrict the input element and the magnetic element from moving in a direction axially aligned with the input element.
9. The system of claim 1 wherein the magnet element is positionable in a first position relative to the sensing element, and the magnet element is movable away from the first position to a second position relative to the sensing element, and further comprising an urging element coupled to the magnet element and configured to provide an urging force to return the magnet element away from the second position to the first position.
10. The system of claim 1 wherein the input element is positionable in a first position relative to the sensing element, and the input element is movable away from the first position to a second position relative to the sensing element, and further comprising an urging element coupled to the input element and configured to provide an urging force to return the input element away from the second position to the first position.
11. The system of claim 1 wherein the housing has a partially spherical first contact surface, and the input element has a partially spherical second contact surface aligned with the first contact surface and positioned to define a range of motion for the magnet element.
12. The system of claim 1 wherein one of the housing and the input element has at least three projections spaced apart from each other and positioned adjacent to a contact surface of the other of the housing and the input elements to form at least three points of contact between the input element and the housing.
13. The system of claim 12 wherein the projections define a path of conductivity for grounding.
14. The system of claim 12 wherein the magnet element is positionable in a first position relative to the sensing element, and the magnet element is movable away from the first position to a second position relative to the sensing element, and further comprising an urging element coupled to the magnet element and configured to provide an urging force to return the magnet element away from the second position to the first position.
15. A hall effect system, comprising:
a housing with a first contact surface portion;
an input element coupled to the housing and having a second contact surface portion immediately adjacent to the first contact surface portion, the input element being moveable relative to the housing whereby the second contact surface is moveable relative to the first contact surface to define a range of motion of the input element relative to the housing;
a magnetic element coupled to the input element and being moveable with the input element relative to the housing, the magnetic element being configured to provide a detectable magnetic flux;
a sensing element adjacent to the magnetic element, the sensing element being configured to sense the magnetic flux; and
a processing element coupled to the sensing element and configured to determine a position of the magnetic element relative to the sensing element be determining changes in andor the orientation of the magnetic flux upon movement of the interface element by a user.
16. The system of claim 15 wherein the magnetic element is coupled to the input element and configured to move with the input element as a unit relative to the sensing element.
17. The system of claim 15 wherein the magnetic element is carried by a portion of the input element.
18. The system of claim 15 wherein the housing has a first portion adjacent to the input element and positioned to protect the magnetic element, and the housing has a second portion that supports the sensing element adjacent to the magnetic element.
19. The system of claim 15 wherein the magnet element is positionable in a first position relative to the sensing element, and the magnet element is movable away from the first position to a second position relative to the sensing element, and further comprising an urging element coupled to the magnet element and configured to provide an urging force to return the magnet element away from the second position to the first position.
20. The system of claim 1 wherein one of the housing and the input element has at least three projections spaced apart from each other to define the first or second contact surface and positioned adjacent to the other the first and second contact surface to form at least three points of contact between the input element and the housing.
The claims below are in addition to those above.
All refrences to claim(s) which appear below refer to the numbering after this setence.
1. A testable pipe joint for coupling first and second pipe sections of a pipe system, comprising:
a spigot ring for use with the first pipe section, the spigot ring having an exterior surface and an interior surface;
a first circumferential groove formed in said exterior surface of said spigot ring for receiving a test gasket;
at least one second circumferential groove formed in said exterior surface of said spigot ring for receiving a pipe seal gasket;
a bell ring for use with the second pipe section and configured to engage said spigot ring, said bell ring having an interior surface sized to receive at least a portion of said spigot ring, said interior surface of said bell ring including a circumferential groove;
a locking ring disposed within said circumferential groove of said bell ring and having a diameter adjustable between an expanded state and a contracted state, wherein said locking ring accommodates engagement of said spigot ring and said bell ring in said expanded state, and wherein said locking ring clamps said bell ring and said spigot ring in said contracted state, said locking ring having first and second ends selectively adjustable between said expanded and contracted states by a fastener, said fastener operatively securing said first and second ends of said locking ring;
a test gasket disposed within said first circumferential groove of said spigot ring;
a pipe seal gasket disposed within said second circumferential groove of said spigot ring, said test gasket and said pipe seal gasket defining an annular space therebetween; and
a pressure port in fluid communication with said annular space between said test gasket and said pipe seal gasket.
2. The testable joint of claim 1, wherein said pressure port is accessible from said interior surface of said spigot ring.
3. A testable pipe joint for coupling first and second pipe sections of a pipe system, comprising:
a spigot ring for use with the first pipe section, the spigot ring having an exterior surface and an interior surface;
a first circumferential groove formed in said exterior surface of said spigot ring for receiving a test gasket;
at least one second circumferential groove formed in said exterior surface of said spigot ring for receiving a pipe seal gasket;
a bell ring for use with the second pipe section and configured to engage said spigot ring, said bell ring having an interior surface sized to receive at least a portion of said spigot ring, said interior surface of said bell ring including a circumferential groove;
a locking ring disposed within said circumferential groove of said bell ring and having a diameter adjustable between an expanded state and a contracted state, wherein said locking ring accommodates engagement of said spigot ring and said bell ring in said expanded state, and wherein said locking ring clamps said bell ring and said spigot ring in said contracted state;
a test gasket disposed within said first circumferential groove of said spigot ring;
a pipe seal gasket disposed within said second circumferential groove of said spigot ring, said test gasket and said pipe seal gasket defining an annular space therebetween; and
a pressure port in fluid communication with said annular space between said test gasket and said pipe seal gasket;
wherein said pressure port is accessible from said exterior surface of said spigot ring, the testable joint further comprising a conduit disposed between and in fluid communication with said pressure port and said annular space between said test gasket and said pipe seal gasket.
4. A spigot ring for coupling a first pipe to a second pipe, the second pipe including a bell ring having an interior surface for coupling to the first pipe and a locking ring that is adjustable between expanded and contracted states, the spigot ring comprising:
an annular spigot body having an exterior surface and an interior surface and defining a passage for transporting fluids therethrough;
a first circumferential groove formed in said exterior surface and configured to receive a test gasket;
at least one second circumferential groove formed in said exterior surface and configured to receive a pipe seal gasket for sealing the joint between the first pipe and the second pipe, said first circumferential groove and said second circumferential groove defining an annular space therebetween;
an engagement member disposed at a distal end of said spigot body, said engagement member configured to be received within the interior surface of the bell ring and to engage the locking ring when the locking ring is in the contracted state to thereby secure said spigot ring to the bell ring; and
a pressure port in the spigot ring, said pressure port in fluid communication with said annular space between said first circumferential groove and said second circumferential groove.
5. The spigot ring of claim 4, wherein said pressure port is accessible from said interior surface of said spigot body.
6. The spigot ring of claim 4, wherein said pressure port is accessible from said exterior surface of said spigot body, said spigot further comprising a conduit disposed between and in fluid communication with said pressure port and said annular space between said first circumferential groove and said second circumferential groove.
7. A pipe couplable to a pipe system, the pipe system including a bell ring having an interior surface for coupling to the pipe and a locking ring that is adjustable between expanded and contracted states, the pipe comprising:
a pipe section having first and second ends;
at least one spigot ring disposed at one of said first and second ends and configured to be received within the interior surface of the bell ring and to engage the locking ring when the locking ring is in the contracted state to thereby secure said spigot ring to the bell ring, said spigot ring having an interior surface and an exterior surface and defining a passage for transporting fluids therethrough;
a first circumferential groove formed in said exterior surface and configured to receive a test gasket;
at least one second circumferential groove formed in said exterior surface and configured to receive a pipe seal gasket;
a test gasket disposed within said first circumferential groove;
a pipe seal gasket disposed within said second circumferential groove, said test gasket and said pipe seal gasket defining an annular space therebetween; and
a pressure port formed in said spigot ring and in fluid communication with said annular space between said test gasket and said pipe seal gasket.
8. The pipe of claim 7, wherein said pressure port is accessible from said interior surface of said spigot ring.
9. The pipe of claim 7, wherein said pressure port is accessible from said exterior surface of said spigot ring, the pipe further comprising a conduit disposed between and in fluid communication with said pressure port and said annular space.
10. A pipe assembly, comprising:
first and second pipe sections each having first and second ends;
a spigot ring disposed on said first end of said first pipe section, said spigot ring having an interior surface and an exterior surface and defining a passage for transporting fluids therethrough;
a first circumferential groove formed in said exterior surface of said spigot ring and configured to receive a test gasket;
at least one second circumferential groove formed in said exterior surface of said spigot ring and configured to receive a pipe seal gasket;
a bell ring disposed on said second end of said second pipe section and configured to engage said spigot ring, said bell ring having an interior surface sized to receive at least a portion of said spigot ring, said interior surface having a circumferential groove;
a locking ring disposed within said circumferential groove of said bell ring and having a diameter adjustable between an expanded state and a contracted state, wherein said locking ring accommodates engagement of said spigot ring and said bell
ring in said expanded state, and engages said bell ring to said spigot ring in said contracted state;
a test gasket disposed in said first circumferential groove formed in said spigot ring;
a pipe seal gasket disposed in said second circumferential groove formed in said spigot ring, said test gasket and said pipe seal gasket defining an annular space therebetween; and
a pressure port formed in said spigot ring and in fluid communication with said annular space between said test gasket and said pipe seal gasket.
11. A method of testing a pipe assembly having at least first and second pipe sections coupled together by a spigot ring and a bell ring, the spigot ring and bell ring defining a passage for transporting fluids therethrough, the bell ring having a locking ring that contracts to engage the bell ring to the spigot ring, the spigot ring having a pipe seal gasket and a test gasket defining an annular test space therebetween, and a pressure port in the spigot ring and in communication with the annular test space, the method comprising:
coupling a pressure source to the pressure port and the annular test space;
pressurizing the annular test space to test the seal of the pipe seal gasket; and
monitoring the pressure in the annular test space.
12. The method of claim 11, wherein coupling the pressure source to the pressure port includes accessing the pressure port from a location interior to the pipe assembly.
13. The method of claim 11, wherein coupling the pressure source to the pressure port includes accessing the pressure port from a location exterior to the pipe assembly.
14. The pipe joint of claim 1, further comprising an aperture formed in said spigot ring and communicating with said first circumferential groove to facilitate fluid communication between said pressure port and said annular space.
15. The pipe joint of claim 3, wherein said conduit extends along said interior surface of said spigot ring.
16. The spigot ring of claim 4, further comprising an aperture formed in said spigot body and communicating with said first circumferential groove to facilitate fluid communication between said pressure port and said annular space.
17. The spigot ring of claim 6, wherein said conduit extends along said interior surface of said spigot body.
18. The pipe of claim 7, further comprising an aperture formed in said spigot ring and communicating with said first circumferential groove to facilitate fluid communication between said pressure port and said annular space.
19. The pipe of claim 9, wherein said conduit extends along said interior surface of said spigot ring.
20. The pipe assembly of claim 10, further comprising an aperture formed in said spigot ring and communicating with said first circumferential groove to facilitate fluid communication between said pressure port and said annular space.