SENSORS AND METHODS AND APPARATUS RELATING TO SAME

US 20110110792A1
Filed: 11/12/2009
Published: 05/12/2011
Est. Priority Date: 11/12/2009
Status: Abandoned Application

First Claim

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1. A capacitive sensor comprising:

a sensor housing defining a cavity;

a capacitor having a first electrode located within the cavity of the sensor housing and a second electrode located at least partially external to the sensor housing thereby creating a gap between the second electrode and the sensor housing to reduce the risk of mineral buildup between the capacitor electrodes; and

a dielectric connecting the first and second electrodes to form a capacitor having a readable capacitance, the dielectric having a first part made of an insulative material and a second part made of a liquid having a level that changes with respect to the insulative material which causes a change in the capacitance of the capacitor.

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Abstract

In one form a capacitive sensor is disclosed for immersion into a fluid, the capacitive sensor having a housing and first and second electrodes with the first electrode being disposed at least partially within the housing and electrically connected to a circuit, the second electrode being electrically connected to the circuit via an electrical connection and physically separated from the housing containing at least a portion of the first electrode so that at least a portion of the electrical connection or second electrode is located above or outside of the fluid to reduce the risk that minerals will form between the electrodes. In other forms, capacitors, capacitive sensors, pump controls and systems utilizing these features are disclosed along with methods and apparatus relating to same. In yet other forms additional sensors such as current sensors, thermal sensors, speed sensors, torque sensors and Hall Effect sensors are disclosed for use alone or in combination with said capacitive sensor for detecting fluid level and/or controlling pumps.

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28 Claims

1. A capacitive sensor comprising:
- a sensor housing defining a cavity;
  
  a capacitor having a first electrode located within the cavity of the sensor housing and a second electrode located at least partially external to the sensor housing thereby creating a gap between the second electrode and the sensor housing to reduce the risk of mineral buildup between the capacitor electrodes; and
  
  a dielectric connecting the first and second electrodes to form a capacitor having a readable capacitance, the dielectric having a first part made of an insulative material and a second part made of a liquid having a level that changes with respect to the insulative material which causes a change in the capacitance of the capacitor.
- View Dependent Claims (2, 3)
- - 2. The capacitive sensor of claim 1 wherein at least a portion of the sensor housing forms at least a portion of the insulative material of the dielectric and the second electrode is located completely external to the capacitor body so that there is at least a gap between the second electrode and the sensor housing to prevent salt bridges from forming between the electrodes.
  - 3. The capacitive sensor of claim 2 wherein the sensor housing has a vertical longitudinal axis and defines an upper housing portion and a lower housing portion and the first electrode is located on an elongated circuit board inserted into the cavity of the sensor housing positioning the first electrode against an inner surface of the sensor housing at the lower housing portion thereof and the second electrode extends up from the elongated circuit board out of a top opening of the sensor housing at the upper housing portion thereof and outward from the sensor housing and extends back down towards the lower portion of the sensor housing generally parallel to an exterior surface of the sensor housing.

4. A capacitive sensor for immersing in a fluid with at least one external electrode for reducing the risk of mineral buildup between capacitor electrodes, the sensor comprising:
- a sensor housing made up of an insulative material and defining a cavity within which a circuit is disposed;
  
  a capacitor having a first electrode electrically connected to the circuit and located within the cavity of the sensor housing and a second electrode electrically connected to the circuit via an electrical connection and spaced apart from the sensor housing such that at least a portion of the electrical connection or the second electrode is positioned out of the fluid within which the capacitive sensor is immersed in order to create a physical separation between the second electrode and the sensor housing to reduce the risk of mineral buildup between the capacitor electrodes; and
  
  a dielectric connected between the first and second electrodes to form a capacitor having a readable capacitance, the dielectric having a first part made of at least a portion of the insulative material of the sensor housing and a second part made of at least a portion of the liquid, the liquid having a level that changes with respect to the insulative material which causes a change in the properties of the dielectric and the capacitance of the capacitor.

5. A pump control with external probe comprising:
- a housing defining a cavity;
  
  a controller for actuating a pump connected to a circuit disposed in the cavity of the housing;
  
  a capacitive sensor connected to the controller and having a first electrode probe disposed within the cavity of the housing and a second electrode probe positioned outside of the housing and electrically connected to the circuit within the housing; and
  
  a switch connecting the controller to the pump and operated by the controller for actuating the pump.
- View Dependent Claims (6, 7, 8)
- - 6. The pump control of claim 5 wherein the circuit is disposed in the cavity of the housing such that the first electrode probe of the capacitor is positioned adjacent an inner surface of the housing defined by the cavity and the pump control is immersed in a fluid such that the portion of the housing adjacent the first electrode probe and the fluid within which the pump control is immersed make up at least a portion of the dielectric between the first and second electrode probes of the capacitive sensor and form a capacitor with a readable capacitance.
  - 7. The pump control of claim 6 wherein the housing has a vertical longitudinal axis and defines an upper housing portion and a lower housing portion and the first electrode probe is located on an elongated circuit board inserted into the cavity of the sensor housing positioning the first electrode against the inner surface of the housing at the lower housing portion thereof and the second electrode extends up from the elongated circuit board out of a top opening of the housing at the upper housing portion thereof and outward from the sensor housing and extends back down towards the lower portion of the sensor housing generally parallel to an exterior surface of the sensor housing.
  - 8. The pump control of claim 6 wherein the fluid has a level that changes with respect to the housing which causes a change in the capacitance of the capacitor and the controller actuates the pump when a high fluid position is detected via the capacitive sensor reading a capacitance of a predetermined amount.

9. A pump control comprising:
- a first sensor using a first type of sensing for detecting a first fluid position;
  
  a second sensor using a second type of sensing different from the first for detecting a second fluid position; and
  
  a controller electrically connected to the first and second sensors and capable of activating a pump when the first sensor detects the first fluid position and de-activating the pump when the second sensor detects the second fluid position.
- View Dependent Claims (10, 11, 12, 13, 14)
- - 10. The pump control of claim 9 wherein the first sensor is a capacitive sensor that detects the first fluid position when a capacitance is detected that corresponds to a high fluid position and the second sensor is a current sensor, a thermal sensor, a speed sensor, a torque sensor or a Hall Effect sensor that detects the second fluid position when a current, a temperature, a speed, a torque or a Hall Effect condition is detected that corresponds to a low fluid position.
  - 11. The pump control of claim 9 wherein the first sensor is a capacitive sensor that detects the first fluid position when a capacitance is detected that corresponds to a high fluid position and the second sensor is a current sensor that detects the second fluid position when a current is detected that corresponds to a low fluid position.
  - 12. The pump control of claim 9 wherein the first sensor is a capacitive sensor that detects the first fluid position when a capacitance is detected that corresponds to a high fluid position and the second sensor is a thermal sensor that detects the second fluid position when a temperature is detected that corresponds to a low fluid position.
  - 13. The pump control of claim 9 wherein the first sensor is a capacitive sensor that detects the first fluid position when a capacitance is detected that corresponds to a high fluid position and the second sensor is a speed or torque sensor that detects the second fluid position when a speed or a torque is detected that corresponds to a low fluid position.
  - 14. The pump control of claim 9 wherein the first sensor is a capacitive sensor that detects the first fluid position when a capacitance is detected that corresponds to a high fluid position and the second sensor is a Hall Effect sensor that detects the second fluid position when a condition is detected that corresponds to a low fluid position.

15. A method of controlling a pump comprising:
- providing a first sensor using a first type of sensing for detecting a first fluid position, a second sensor using a second type of sensing different from the first for detecting a second fluid position, and controller electrically connected to the first and second sensors;
  
  activating a pump via the controller when the first sensor detects the first fluid position; and
  
  de-activating the pump via the controller when the second sensor detects the second fluid position.
- View Dependent Claims (16, 17, 18, 19, 20)
- - 16. The method of claim 15 wherein the first sensor is a capacitive sensor and the second sensor is a current sensor, a thermal sensor, a speed sensor, a torque sensor or a Hall Effect sensor and activating the pump comprises turning on the pump when the capacitive sensor detects a capacitance that corresponds to a high fluid position and de-activating the pump comprises turning off the pump when the current sensor, thermal sensor, speed sensor, torque sensor or Hall Effect sensor detects a condition that corresponds to a low fluid position.
  - 17. The method of claim 15 wherein the first sensor is a capacitive sensor and the second sensor is a current sensor and activating the pump comprises turning on the pump when the capacitive sensor detects a capacitance that corresponds to a high fluid position and de-activating the pump comprises turning off the pump when the current sensor detects a current that corresponds to a low fluid position.
  - 18. The method of claim 15 wherein the first sensor is a capacitive sensor and the second sensor is a thermal sensor and activating the pump comprises turning on the pump when the capacitive sensor detects a capacitance that corresponds to a high fluid position and de-activating the pump comprises turning off the pump when the thermal sensor detects a temperature corresponding to a low fluid position.
  - 19. The method of claim 15 wherein the first sensor is a capacitive sensor and the second sensor is a speed or torque sensor and activating the pump comprises turning on the pump when the capacitive sensor detects a capacitance that corresponds to a high fluid position and de-activating the pump comprises turning off the pump when the speed or torque sensor detects a speed or torque that corresponds to a low fluid position.
  - 20. The method of claim 15 wherein the first sensor is a capacitive sensor and the second sensor is a Hall Effect sensor and activating the pump comprises turning on the pump when the capacitive sensor detects a capacitance that corresponds to a high fluid position and de-activating the pump comprises turning off the pump when the Hall Effect sensor detects a condition that corresponds to a high fluid position.

21. A variable capacitor comprising:
- a capacitor body defining a cavity;
  
  a first electrode located within the cavity of the capacitor body;
  
  a second electrode located at least partially external to the capacitor body; and
  
  a dielectric connecting the first and second electrode to form a capacitor having a readable capacitance, the dielectric having a first part made of an insulative material and a second part made of a liquid having a level that changes with respect to the insulative material which causes a change in the capacitance of the capacitor.
- View Dependent Claims (22)
- - 22. The variable capacitor of claim 21 wherein at least a portion of the capacitor body forms at least a portion of the insulative material of the dielectric and the second electrode is located completely external to the capacitor body.

23. A capacitive sensor comprising:
- a capacitor having a housing and first and second electrodes, the capacitor being at least partially immersed in a liquid having a level that changes in relation to the capacitor and having a variable capacitance depending on the level of the liquid;
  
  a circuit connected to the capacitor to determine the capacitance of the capacitor and thereby determine the level of the liquid; and
  
  wherein the first electrode is located within the capacitor housing and the second electrode is located outside of the capacitor housing and both the first and second electrodes are at least partially immersed in the liquid.
- View Dependent Claims (24)
- - 24. The capacitive sensor of claim 23 wherein the second electrode is covered with an insulative material and together the insulative material, at least a portion of the capacitor housing and the liquid form a dielectric between the first and second electrodes and the capacitance of the capacitor changes in a manner corresponding to the level of the liquid.

25. A method of varying capacitance in a variable capacitor comprising:
- providing a capacitor having a first electrode, a second electrode and a dielectric connecting the first and second electrodes to form a capacitor having a readable capacitance, the first electrode being located in a housing and the second electrode being spaced apart from the first electrode and housing to form a gap therebetween;
  
  submersing at least a portion of the capacitor in a liquid, creating a liquid level with respect to the capacitor; and
  
  changing the capacitance of the capacitor submersed in the liquid by increasing or decreasing the liquid level.

26. A method of determining a level of liquid comprising:
- providing a capacitor at least partially immersed in a liquid having a level that changes in relation to the capacitor, the capacitor having a variable capacitance depending on the level of liquid with a first electrode disposed in a housing and a second electrode positioned outside of the housing containing the first electrode to form a gap therebetween;
  
  using a circuit connected to the capacitor to determine the capacitance of the capacitor; and
  
  determining the level of the liquid based on the capacitance of the capacitor.

27. A method of operating a pump, comprising:
- detecting a capacitance for a capacitor at least partially submerged in a liquid having a level that changes in relation to the capacitor, the capacitor having a plurality of capacitances with each capacitance corresponding to a different liquid level and having a first electrode disposed within a housing and a second electrode positioned outside of the housing to form a gap between the housing within which the first electrode is disposed and the second electrode;
  
  activating a pump when a first capacitance is detected;
  
  determining when the pump should be deactivated when a second capacitance is detected; and
  
  deactivating the pump as determined when the second capacitance was detected.

28. A method of detecting fluid level using a capacitive sensor comprising:
- providing a capacitive sensor having a housing and first and second electrodes for immersion into a fluid having a level that changes in relation to the electrodes, the fluid forming at least part of a dielectric between the electrodes and together the dielectric and electrodes form a capacitor having a capacitance that varies corresponding to the level of the liquid with respect to the electrodes, wherein the first electrode is electrically connected to a circuit and disposed in the housing and the second electrode being spaced apart from the housing and electrically connected to the circuit via an electrical connection to the circuit;
  
  immersing at least a portion of the first and second electrodes into the fluid such that at least a portion of the electrical connection or second electrode remain above or outside of the liquid to physically separate the electrodes and reduce the risk of minerals collecting between the electrodes and interfering with the operation of the capacitive sensor; and
  
  detecting fluid level by determining or monitoring the capacitance of the capacitor.

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Current Assignee
Joseph Kendall Mauro, Michael Patrick Dyer, Philip Anthony Mayleben, Thomas R. Stetter
Original Assignee
Joseph Kendall Mauro, Michael Patrick Dyer, Philip Anthony Mayleben, Thomas R. Stetter
Inventors
Mayleben, Philip Anthony, Dyer, Michael Patrick, Mauro, Joseph Kendall, Stetter, Thomas R.

Application Number

US12/617,377
Publication Number

US 20110110792A1
Time in Patent Office

Days
Field of Search
US Class Current

417/44.1
CPC Class Codes

F04B 49/02   Stopping, starting, unloadi...

F04D 13/08   for submerged use

F04D 15/0218   the condition being a liqui...

G01F 23/265   for discrete levels

G01F 23/266   measuring circuits therefor

G01F 23/268   mounting arrangements of pr...

SENSORS AND METHODS AND APPARATUS RELATING TO SAME

First Claim

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Accused Products

Abstract

117 Citations

28 Claims

Specification

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SENSORS AND METHODS AND APPARATUS RELATING TO SAME

First Claim

0 Assignments

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Subscription Required

0 Petitions

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Accused Products

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Abstract

117 Citations

28 Claims

Specification

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Use Cases

Quick Links

Others