CURRENT SENSING SWITCH FOR USE WITH PUMPS

Abstract

A current sensing switch for use with a pump that is physically separate from the pump and contains a current sensor for measuring the electrical current flowing to the pump as a method of determining whether the pump is operating in low fluid, dry conditions, or with an impeller that has ceased to rotate. When the current drops below or raises above a predetermined value for a predetermined amount of time, the switch electrically disconnects power to the pump and reconnects it periodically to cheek whether the state of the pump has changed.

Claims

1. A switch for a pump comprising: a housing having a plurality of prongs extending therefrom and a plug socket; a circuit board having a relay capable of electrically connecting and disconnecting said prongs to said plug socket; said circuit board further comprising a programmable controller, a current sensor, a data center, a power switch, and a current setting switch; wherein activating said power switch energizes said circuit board and causes said relay to electrically connect said prongs to said plug socket; wherein said current sensor transmits to said data center a measurement of an electric current flowing to said pump through said plug socket; wherein said current setting switch transmits to said data center a current setting value; and wherein said controller compares said measurement from said current sensor to said current setting value such that if said measurement is less than said current setting value for a predetermined amount of time, then said controller causes said relay to electrically disconnect said prongs from said plug socket.

2. The switch for a pump according to claim 1 wherein said housing further comprises a first half and a second half that attach together to enclose said circuit hoard within a waterproofed cavity.

3. The switch for a pump according to claim 1 further comprising a microprocessor within which said data center and said programmable controller are incorporated.

4. The switch for a pump according to claim 1 further comprising a digital display that displays said measurement from said current sensor.

5. The switch for a pump according to claim 1 further comprising a digital display that displays said current setting value.

6. A switch for a pump comprising: a housing having a plurality of prongs extending therefrom and a plug socket; a circuit board comprising a controller, a current sensor, a current setting switch, and a relay capable of electrically connecting and disconnecting said prongs to said plug socket; wherein said current sensor measures an electrical current flowing to said pump; wherein said current setting switch sets a lower current setting value; wherein said controller computes an upper current setting value based on said lower current setting value or based on said electrical current flowing to said pump as measured by said current sensor; wherein said controller causes said relay to electrically disconnect said prongs from said plug socket for a first predetermined time period when said electrical current flowing to said pump as measured by said current sensor is less then said lower current setting value for a few predetermined seconds; and wherein said controller causes said relay to electrically disconnect said prongs from said plug socket for a second predetermined time period when said electrical current flowing to said pump as measured by said current sensor is greater than said upper current setting value for said few predetermined seconds.

7. The switch for a pump according to claim 6 wherein said housing further comprises a first half and a second half that attach together to enclose said circuit board within a waterproofed cavity.

8. The switch for a pump according to claim 6 further comprising a microprocessor within which said controller is incorporated.

9. The switch for a pump according to claim 6 further comprising a digital display that displays said measurement from said current sensor.

10. The switch for a pump according to claim 6 further comprising a digital display that displays said lower current setting value or said upper current setting value.

11. The switch for a pump according to claim 6 wherein said current setting switch can readily vary said lower current setting value so as to maintain said pump within an operating range.

12. The switch for a pump according to claim 6 wherein said current setting switch is immediately accessible without effort, tools, or disassembly.

13. A switch for a pump comprising: a circuit board comprising a current setting switch and a controller capable of electrically connecting and disconnecting said pump from a power supply; wherein said current setting switch sets a lower current setting value; wherein said controller computes an upper current setting value based on said lower current setting value or based on an electrical current flowing to said pump; wherein said controller electrically disconnects said pump for a first predetermined time period when said electrical current flowing to said pump is less than said lower current setting value for a few predetermined seconds; and wherein said controller electrically disconnects said pump for a second predetermined time period when said electrical current flowing to said pump is greater than said upper current setting value for said few predetermined seconds.

14. The switch for a pump according to claim 13 wherein said housing further comprises a first half and a second half that attach together to enclose said circuit board within a waterproofed cavity.

15. The switch for a pump according to claim 13 further comprising a microprocessor within which said controller is incorporated.

16. The switch for a pump according to claim 13 further comprising a digital display that displays said measurement from said current sensor.

17. The switch for a pump according to claim 13 further comprising a digital display that displays said lower current setting value or said upper current setting value.

18. The switch for a pump according to claim 13 wherein said current setting switch can readily vary said lower current setting value so as to maintain said pump within, art operating range.

19. The switch for a pump according to claim 13 wherein said current setting switch is immediately accessible without effort, tools, or disassembly.

Description

DESCRIPTION OF THE DRAWINGS

[0016] The accompanying drawings which are incorporated by reference herein and form part of the specification, illustrate various embodiments of the present invention and together with the description, further serve to explain the principles of the invention and to enable a person skilled in the pertinent art to make and use the invention. In the drawings, like reference numbers indicate identical or functional similar elements. A more complete appreciation of the invention and many of the attendant advantages thereof will be readily obtained as the same becomes better understood by reference to the following detailed description when considered in connection with the accompanying drawings, wherein:

[0017] FIG. 1 is a front perspective view of the pump switch of the present invention.

[0018] FIG. 2 is a front view of the pump switch of the present invention.

[0019] FIG. 3 is a side view of the pump switch of the present invention.

[0020] FIG. 4 is an exploded view of the pump switch of the present invention.

[0021] FIG. 5 is a diagram depicting the pump switch of the present invention connected to a pump.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

[0022] Reference will now be made to the drawings in which various elements of the present invention will be given numerical designations and in which the invention will be discussed so as to enable one skilled, in the art and make use the invention.

[0023] The present invention comprises a pump switch 100 with a housing 10 having prongs 20 of an electrical, plug extending therefrom and an electrical plug socket 30. Inside the housing 10 is a circuit board 40 having a relay that is capable of electrically connecting and disconnecting the electrical plug socket 30 to the prongs 20 of the electrical plug. The circuit board 40 comprises a current sensor, a data center, a controller, a power switch 43, and a current setting switch 44.

[0024] Application of the present invention is with pumps 200. As shown in FIG. 5, a pump 200 has an electrical cord 210 extending therefrom with an electrical plug 215 at the end. The electrical plug 215 is generally plugged in to an electrical plug socket through which electrical current is passed to power up and activate the pump 200. When the pump 200 is activated, a pump motor activates to drive an impeller. When the pump 200 is submerged in fluid, for example, the rotation of the impeller causes the fluid to flow such that the fluid is sucked in through the inlet 230 and pushed out of the outlet 235 of the pump 200.

[0025] However, a problem arises when the pump 200 is not submerged in fluid or when the impeller ceases to rotate. This can occur when the pump 200 has finished pumping out the fluid in which it was submerged or when the impeller is blocked. When the pump 200 operates and is not submerged in fluid or the impeller is blocked, the pump motor can overheat and be permanently damaged.

[0026] The present invention addresses this problem by electrically connecting the circuit board 40 in-line with the electrical plug socket, thus, the power source. Therefore, rather than connecting the electrical plug 215 directly to the electrical plug socket, the plug 215 is connected to the electrical plug socket 30 in the pump switch 100 of the present invention. The prongs 20 of the electrical plug in the pump switch 100 of the present invention is then connected to the electrical plug socket to which the plug 215 would normally be connected.

[0027] The current sensor 41 of the circuit board 40 measures the electrical current passing from the pump switch 100 of the present invention to the pump 200 through the plug 215. This is measured because the electrical current passing to the pump 200 is proportional to the work being done by the pump 200. Thus, measuring the electrical current can allow the pump switch 100 determine whether the pump is actually pumping fluid, just spinning in air, or if the impeller is stuck.

[0028] The current setting switch 44 is used to set a lower electrical current limit or a lower current setting value for the pump switch 100. Thus, if the electrical current passing to the pump 200, as measured by the current sensor 41, fails below the lower current setting value, then the pump switch 100 terminates the electrical current flow to the pump 200 by electrically disconnecting the pump 200 from the power source. As shown in FIG. 3, in the preferred embodiment of the present invention, the current setting switch 44 is a dial switch that can be rotated to vary or change the lower current setting value. The current setting switch 44 is readily accessible by the user to vary or change the lower current setting value. Thus, the pump switch 100 of the present invention can be utilized with different types of pumps and fluids of varying viscosity and other characteristics. Depending on the type of pump and type of fluid used, the user can readily change the lower current setting value using the current setting switch 44 to maintain said pump switch. 100 within an acceptable operating range. Although the preferred embodiment of the present invention utilizes a dial switch for the current setting switch 44, it is understood that the current setting switch 44 can be a digital switch, a push button switch, a keypad, and the like.

[0029] When the user sets the current setting switch 44 to a particular setting, the digital value of the lower current setting value is transmitted and stored within the data center in the circuit board 40. The controller then calculates an upper current setting value based on the lower current setting value and the average electrical current passing to the pump 200 within a predetermined time period as measured by the current sensor 41. Then the digital value of the electrical current passing to the pump 200 is periodically transmitted to the data center and compared with the lower and upper current setting values, lithe electrical current is less than the lower current setting value or higher than the upper current setting value, then the pump switch 100 disconnects the pump 200 from the power source, thus, terminating the flow of current to the pump 200. The connecting and disconnecting of the pump 200 from the power source is accomplished by the relay by electrically connecting or disconnecting the electrical plug socket to the prongs.

[0030] However, to avoid false readings, the pump switch 100 of the present invention incorporates a delay of a few predetermined seconds. Thus, when the electrical current drops below the lower current setting value or rises above the upper current setting value, the pump switch 100 waits for the few predetermined seconds before disconnecting the pump 200 from the power source. If the electrical current is below or above the lower or upper current setting values for the duration of the few predetermined seconds, then the pump switch 100 disconnects the pump 200 from the power source. This delay allows the pump switch 100 to distinguish between a change in the electrical current caused by actual work done by the pump 200 or by a change caused by other circumstances.

[0031] If the pump 200 is disconnected by the pump switch 100 due to a drop in the electrical current below the lower current setting value, then the pump 200 remains disconnected for a first predetermined time period after which the pump switch 100 reconnects the pump 200 and recalculates whether the electrical current is still below the lower current setting value for the few predetermined seconds. If so, then the pump 200 is again disconnected by the pump switch 100 for the first predetermined time period after which the pump switch 100 repeats the cycle. This cycle is repeated by the pump switch 100 every first predetermined time period until, the electrical current, as measured by the current sensor 41, is higher than the lower current setting value or until the pump switch 100 is disconnected from its power supply. The repetition of this cycle is an important aspect of the pump switch 100 of the present invention as it ensures that that pump 200 pumps out all of the intended water or fluid. For example, in a situation where a basement of a house is being flooded by water from a faulty plumbing pipe or rain, the rate of water pumped out of the basement by the pump 200 may be greater than the rate of water leaking or flowing into the basement. Thus, at a certain point, all or most of the water may be pumped out of the basement by the pump 200. Thus, it is preferred that the pump 200 be turned off or deactivated. However, the water may not have stopped from leaking or flowing into the basement, the water may flow into the basement at a lower rate than the pump 200 can pump it out of the basement. Thus, if the pump 200 is turned, off or disconnected indefinitely, then the water will continue to flood the basement during the indefinite time that the pump is left inoperable. Accordingly, the pump switch 100 of the present invention, periodically turn on the pump 200 to compare the electrical current to the lower current setting value so as to check whether any water or fluid has returned. In the preferred embodiment of the present invention, the pump switch 100 powers up the pump 200 periodically after every first predetermined time period, which can be between 5 to 10 minutes. The connecting and disconnecting of the pump 200 from the power source is accomplished by the relay by electrically connecting or disconnecting the electrical plug socket to the prongs.

[0032] Similarly, circumstances may arise in which the inlet 230 of the pump 200 is blocked so as to prevent any water from entering the pump 200 and creating a vacuum therewithin. Alternatively, the impeller of the pump 200 may be physically blocked or trapped. In both scenarios, the impeller may cease its rotation causing the electrical current to spike or rise above the upper current setting value. Allowing the pump 200 to operate when the impeller is trapped or ceases its rotation can cause substantial overheating and damage to the pump 200. As such, the pump switch 100 of the present invention terminates the current flow to the pump 200 when the electrical current passing from the pump switch 100 to the pump 200 is greater than the upper current setting value for the duration of the few predetermined seconds.

[0033] If the pump 200 is disconnected by the pump switch 100 due to an increase in the electrical current above the upper current setting value, then the pump 200 remains disconnected for a second predetermined time period after which the pump switch 100 reconnects the pump 200 and recalculates whether the electrical current is still above the upper current setting value for the few predetermined seconds. If so, then the pump 200 is again disconnected by the pump switch 100 for the second predetermined time period after which the pump switch 100 repeats the cycle. This cycle is repeated by the pump switch 100 every second predetermined time period until the electrical current, as measured by the current sensor 41, is lower than the upper current setting value or until the pump switch 100 is disconnected from its power supply. The repetition of this cycle is an important aspect of the pump switch 100 of the present invention as it ensures that the pump 200 pumps out all of the intended water or fluid. For example, in situations when the impeller is blocked, the water may continue to flood a basement. Thus, if the pump 200 is turned off or disconnected indefinitely, then the water may continue to flood the basement even if the impeller is unblocked at a later time. Accordingly, the pump switch 100 of the present invention, periodically turns on the pump 200 to compare the electrical current to the upper current setting value so as to check whether the impeller is still blocked. In the preferred embodiment of the present invention, the pump switch 100 powers up the pump 200 periodically after every second predetermined time period, which can be once or twice per day. The connecting and disconnecting of the pump 200 from the power source is accomplished by the relay by electrically connecting or disconnecting the electrical plug socket to the prongs.

[0034] The housing 10 of the pump switch 100 comprises a first half 11 and a second half 12 that attach together with the circuit board 40 in between, as shown in FIG. 4. The housing 10 would provide weatherproofing of the pump switch 100 by the manner in which it encloses the circuit board 40 therewithin. The housing 10 would incorporate an o-ring or gasket in between said first half 11 and said second half 12 to protect the circuit board 40 from fluid exposure. Furthermore, a radial seal 13 would be used in the current setting switch 44 to further protect the circuit board 40 from fluid exposure. Finally, the power switch 43 would be encapsulated within a flexible thermoplastic protector to even further protect the circuit board 40 from fluid exposure.

[0035] It is understood that the described embodiments of the present invention are illustrative only, and that modifications thereof ma occur to those skilled in the art. Accordingly, this invention is not to be regarded as limited to the embodiments disclosed, but to be limited only as defined by the appended claims herein.