Tilt sensor

US 10,317,208 B2
Filed: 03/03/2017
Issued: 06/11/2019
Est. Priority Date: 03/03/2017
Status: Active Grant

First Claim

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1. A tilt sensor configured to detect when the tilt sensor is not vertical, comprising:

a chamber defined by a top chamber end, a bottom chamber end, a first axis running from said top chamber end to said bottom chamber end, and one or more chamber walls connecting said top chamber end and said bottom chamber end;

a low point located within said chamber;

a metallic ball within said chamber, said metallic ball free to move about said chamber such that, when said first axis is vertical, said metallic ball will come to rest at said low point; and

an inductive sensor, said inductive sensor attached to said chamber and directed at said low point such that, wherein said inductive sensor is configured such that when said first axis is vertical said inductive sensor detects the presence of said metallic ball in said low point;

wherein, said inductive sensor is configured such that upon failing to detect the presence of said metallic ball, said inductive sensor transmits a signal that said metallic ball is not in said low point.

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Abstract

A tilt sensor for signaling when the tilt sensor is not vertical. The tilt sensor includes a metallic ball that is free to move and capable of resting at a low point when the tilt sensor is vertical. A proximity sensor directed at the low point communicates when the metallic ball has deviated from its position of repose, indicating that the sensor is no longer vertical.

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20 Claims

1. A tilt sensor configured to detect when the tilt sensor is not vertical, comprising:
- a chamber defined by a top chamber end, a bottom chamber end, a first axis running from said top chamber end to said bottom chamber end, and one or more chamber walls connecting said top chamber end and said bottom chamber end;
  
  a low point located within said chamber;
  
  a metallic ball within said chamber, said metallic ball free to move about said chamber such that, when said first axis is vertical, said metallic ball will come to rest at said low point; and
  
  an inductive sensor, said inductive sensor attached to said chamber and directed at said low point such that, wherein said inductive sensor is configured such that when said first axis is vertical said inductive sensor detects the presence of said metallic ball in said low point;
  
  wherein, said inductive sensor is configured such that upon failing to detect the presence of said metallic ball, said inductive sensor transmits a signal that said metallic ball is not in said low point.
- View Dependent Claims (2, 3, 4, 5, 6, 7, 8)
- - 2. The tilt sensor of claim 1 wherein said inductive sensor is attached to a prox holder configured to securely hold said inductive sensor.
  - 3. The tilt sensor of claim 2 wherein said prox holder is located within said chamber.
  - 4. The tilt sensor of claim 3 wherein said prox holder is removable from said chamber.
  - 5. The tilt sensor of claim 1 wherein said low point is located on an interior surface of said bottom chamber end.
  - 6. The tilt sensor of claim 5 wherein said low point is defined as the apex of an inverted cone.
  - 7. The tilt sensor of claim 1 wherein the interior of said chamber is cylindrical.
  - 8. The tilt sensor of claim 1 wherein said chamber includes an aperture providing egress for the transmission of said signal.

9. A tilt sensor configured to detect when the tilt sensor is not vertical, comprising:
- a chamber having a cylindrical interior and defined by a top chamber end, a bottom chamber end, a first axis running from said top chamber end to said bottom chamber end, and one or more chamber walls connecting said top chamber end and said bottom chamber end;
  
  a low point contained in an interior surface of said bottom chamber end, said low point being defined as the apex of an inverted cone;
  
  a metallic ball within said chamber, said metallic ball free to move about said chamber such that, when said first axis is vertical, said metallic ball will come to rest at said low point;
  
  a prox holder configured to securely hold an inductive sensor, said prox holder positioned within said chamber and removable from said chamber; and
  
  said inductive sensor securely attached to said prox holder, said prox holder located within said chamber such that said inductive sensor is directed at said low point and configured such that when said first axis is vertical said inductive sensor detects the presence of said metallic ball;
  
  wherein said inductive sensor is configured such that upon failing to detect the presence of said metallic ball, said inductive sensor transmits a signal that said metallic ball is not in said low point.
- View Dependent Claims (10, 11, 12, 13, 14, 15, 16, 17, 18, 19)
- - 10. The tilt sensor of claim 9 wherein said prox holder is positioned within said chamber and normal to said first axis such that, when installed, said prox holder severs the interior of said chamber, defining a lower sub-chamber defined by the void within said chamber and below said prox holder and an upper sub-chamber defined by the void within said chamber and above said prox holder, wherein said low point and said metallic ball both being contained in either the upper sub-chamber or the lower sub-chamber.
  - 11. The tilt sensor of claim 10 wherein a recess is defined within one of said top surface or said bottom surface of said prox holder and said inductive sensor is secured by said prox holder through the use of complimentary threading within said recess and surrounding the outer surface of said inductive sensor.
  - 12. The tilt sensor of claim 11 wherein the installed depth of said inductive sensor relative to said recess is controlled through the use of an anchor.
  - 13. The tilt sensor of claim 12 wherein said anchor is a nut threaded around said inductive sensor and abutting said prox holder.
  - 14. The tilt sensor of claim 11 wherein the metallic ball is contained in said lower sub-chamber, said low point is defined by said interior of said bottom chamber end, the bottom surface of said prox holder has a contour complementary to the interior of said bottom chamber end, and the top surface of said prox holder contains said recess designed to receive said inductive sensor.
  - 15. The tilt sensor of claim 11 wherein the metallic ball is located in said upper sub-chamber, the low point is defined by the top surface of said prox holder, and the bottom surface of said prox holder contains a recess designed to receive said inductive sensor.
  - 16. The tilt sensor of claim 10 wherein the interior of said one or more chamber walls and the circumference of said prox holder are complementarily threaded to allow for installation and removal of said prox holder.
  - 17. The tilt sensor of claim 16 wherein at the terminus of the threads on the interior of said one or more chamber walls is located a prox holder seat configured to prevent said prox holder from traveling further into said chamber.
  - 18. The tilt sensor of claim 10 wherein a spacer is located between said one or more chamber walls and said prox holder such the material integrity of the prox holder and the chamber walls is preserved.
  - 19. The tilt sensor of claim 10 wherein a gasket is placed between said one or more chamber walls and said prox holder to prohibit the infiltration of fluids and solids between said lower sub-chamber and said upper sub-chamber.

20. A tilt sensor configured to detect when the tilt sensor is not vertical, comprising:
- a chamber having a cylindrical interior and defined by a top chamber end, a bottom chamber end, a first axis running from the top chamber end to the bottom chamber end, and one or more chamber walls connecting said top chamber end and said bottom chamber end;
  
  a low point located on an interior surface of said bottom chamber end, said low point being defined as the apex of an inverted cone;
  
  a prox holder being circular in shape and located within said chamber normal to said first axis, configured to securely hold an inductive sensor, wherein the top surface of said prox holder contains a recess designed to receive an inductive sensor, and wherein the bottom surface of said prox holder has a contour complementary to said interior surface of said bottom chamber end;
  
  said prox holder being removable via complimentary threading located along the circumference of said prox holder and the interior of said one or more chamber walls such that, when installed, said prox holder severs the interior of said chamber, creating a lower sub-chamber defined by the void within said chamber and below said prox holder, and an upper sub-chamber, defined by the void within said chamber and above said prox holder,a prox holder seat located at the terminus of the threading on the interior of said one or more chamber walls preventing said prox holder from traveling further into said chamber;
  
  a spacer located between said one or more chamber walls and said prox holder such the material integrity of the prox holder and the chamber walls is preserved;
  
  a gasket positioned between said one or more chamber walls and said prox holder such that said lower sub-chamber is impermeable to fluids and solids;
  
  a metallic ball within said lower sub-chamber, said metallic ball free to move about said lower sub-chamber such that, when said first axis is vertical, said metallic ball will come to rest at said low point;
  
  an inductive sensor installed in said prox holder through the use of complimentary threading within said recess in the top surface of said prox holder and surrounding the outer surface of said inductive sensor;
  
  a nut threaded around said inductive sensor and abutting the top surface of said prox holder, said nut used to adjust and maintain the position of said inductive sensor relative to said recess; and
  
  said prox holder with attached inductive sensor positioned within said chamber such that said inductive sensor is directed at said low point such that, wherein said inductive sensor is configured such that when said first axis is vertical said inductive sensor detects the presence of said metallic ball;
  
  wherein said inductive sensor is configured such that upon failing to recognize the presence of said metallic ball, said inductive sensor transmits a signal that said metallic ball is not in said low point.

Specification

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Litigation Campaign Assessment

Current Assignee
Anton M. Walters, Brent Muller, Philip Schafer
Original Assignee
Anton M. Walters, Brent Muller, Philip Schafer
Inventors
Schafer, Philip, Walters, Anton M, Muller, Brent
Primary Examiner(s)
Seo, Justin
Assistant Examiner(s)
Courson, Tania C

Application Number

US15/449,566
Publication Number

US 20180252523A1
Time in Patent Office

830 Days
Field of Search

3336611, 3336625, 3336626, 33368, 33401, 33402
US Class Current
CPC Class Codes

G01C 2009/064   inductive

G01C 2009/107   spheres

G01C 9/06   Electric or photoelectric i...

G01C 9/10   by using rolling bodies , e...

Tilt sensor

First Claim

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Abstract

42 Citations

20 Claims

Specification

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Tilt sensor

First Claim

0 Assignments

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Subscription Required

0 Petitions

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Accused Products

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Abstract

42 Citations

20 Claims

Specification

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Solutions

Use Cases

Quick Links