The present invention generally relates to fluid pumps, and more specifically, fluid pumps with a temperature sensing mechanism.
Fluid pumps can be included within various fluid reservoirs for moving a fluid from within the reservoir to within another portion of the mechanism. Such pumps are configured to be submerged within the reservoir.
According to one aspect of the present invention, a fluid pump includes a pump element in communication with an inlet and an outlet. Rotation of the pump element generates a suction at the inlet and pressure at the outlet. The suction and pressure cooperate to move a fluid through a fluid path. An accessory fluid path is in communication with the inlet and outlet. The accessory fluid path includes a thermistor in communication with the accessory fluid path. The thermistor monitors a temperature of the fluid within the accessory fluid path.
According to another aspect of the present invention, a fluid pump includes a pump element in communication with a fluid path. An accessory fluid path defines a portion of the fluid path. A shadow port is in communication with the pump element, wherein the pump element and the shadow port regulate a flow of a fluid between a primary flow of the fluid to an outlet. An excess flow of the fluid to the accessory fluid path, wherein operation of the pump element in conjunction with the shadow port, promotes the primary flow of the fluid toward the outlet and simultaneously promotes the excess flow of the fluid through the accessory fluid path. The excess flow of the fluid through the accessory fluid path directly engages a thermistor disposed within the accessory fluid path. The thermistor measures a fluid temperature of the excess flow of the fluid within the accessory fluid path.
According to another aspect of the present invention, a method of operating a fluid pump includes activating a pump element to draw a fluid into a fluid path. The pump element operates to direct a fluid to a position that defines a shadow port having an orifice. The fluid is divided into a primary flow of the fluid toward an outlet of the fluid path and an excess flow of the fluid through the orifice and into an accessory fluid path. The excess flow of the fluid is directed to a thermistor. A fluid temperature of the excess flow of the fluid in the accessory fluid path is measured. The excess flow of the fluid is directed toward one of an inlet and the outlet of the fluid path.
These and other aspects, objects, and features of the present invention will be understood and appreciated by those skilled in the art upon studying the following specification, claims, and appended drawings.
In the drawings:
For purposes of description herein, the terms “upper,” “lower,” “right,” “left,” “rear,” “front,” “vertical,” “horizontal,” and derivatives thereof shall relate to the invention as oriented in
As shown in
Referring again to
Referring again to
The fluid 16 is divided between a regulated primary flow 54 of the fluid 16 and the remaining fluid 16 that defines an excess flow 56 of the fluid 16. In regulating the flow of fluid 16 from the outlet shadow port 60 and orifice 62, the primary flow 54 is a predetermined amount of the fluid 16 that is directed to the outlet 22. By dividing the fluid 16, the excess flow 56 of fluid 16 that is not part of the regulated primary flow 54 of the fluid 16 is directed through the orifice 62 and into the accessory fluid path 30. In this manner, the gerotor 18 pushes the primary flow 54 of the fluid 16 through the outlet 22 and simultaneously pushes the excess flow 56 of the fluid 16 through the orifice 62 and into the accessory fluid path 30. Directing the movement of the excess flow 56 of fluid 16 helps to ensure that there is a continuous or substantially continuous flow of fluid 16 across the thermistor 14. Additionally, this configuration of the accessory fluid path 30 in relation to the outlet shadow port 60 and orifice 62 also helps to ensure that the temperature of the excess flow 56 of the fluid 16 is at least substantially similar to the primary flow 54 of fluid 16 that is directed through the outlet 22. This configuration helps to provide real time or substantially real time temperature measurements of the fluid 16.
In this disclosed device, the accessory fluid path 30 is placed in communication with the outlet shadow port 60 through the orifice 62 that controls the excess flow 56 of the fluid 16 from the outlet shadow port 60 and into the accessory fluid path 30. From the orifice 62 at the outlet shadow port 60, the excess flow 56 of fluid 16 flows around at least a portion of the rotor assembly 52, but within the housing 64 of the fluid pump 12. After passing along the side 66 of the rotor assembly 52, the excess flow 56 of fluid 16 is directed along an inner surface 68 of the PCB housing assembly 10 where the thermistor 14 is located. The inner surface 68 of the PCB housing assembly 10 includes contours 70 that are configured to direct the excess flow 56 of fluid 16 from the sides 66 of the rotor assembly 52 along the contours 70, into engagement with the thermistor 14, and to a central portion 72 of the PCB housing assembly 10. In this manner, the contours 70 and central portion 72 of the inner surface 68 of the PCB housing assembly 10 at least partially defines the thermistor flow path 50 and the accessory fluid path 30. The central portion 72 of the PCB housing assembly 10 is in communication with a channel 80 of the drive shaft 46. This channel 80 of the drive shaft 46 extends through the center of the drive shaft 46 and the rotor assembly 52 and up through the gerotor 18 and to a recirculation path 82 that recombines the excess flow 56 of the fluid 16 with fluid 16 entering the inlet 20. In this manner, the excess flow 56 of the fluid 16 is draw back into the inlet 20 by the suction 24 generated by the gerotor 18. The recombined fluid 16 is then delivered via the gerotor 18 and is divided into the primary and excess flows 54, 56 of fluid 16 as described above. In this configuration, a portion of the excess flow 56 upon leaving the recirculation path 82 may be divided again as part of the excess flow 56. It is contemplated that the excess flow 56 from the recirculation path 82 will be sufficiently mixed with the fluid 16 entering the inlet 20. Accordingly, the amount of the excess flow 56 that is divided again into a portion of the excess flow 56 is substantially minimal. The effects of a portion of the excess flow 56 being directly recirculated again through the accessory fluid path 30 as part of the excess flow 56 will have minimal effects on the temperature measurements of the thermistor 14.
In various embodiments, the recirculation path 82 may direct the excess flow 56 of fluid 16 from the accessory fluid path 30 to the outlet 22 of the fluid pump 12. In this manner, the excess flow 56 can be at least partially re-combined with the primary flow 54 of fluid 16 that is moved through the outlet 22.
Referring again to
Within conventional fluid pumps 12, very little fluid 16 is moved in and around the motor cavity. As such, placing a thermostat or other temperature sensing device within this area provides little, if any, temperature-related information.
Referring again to
It is contemplated that the fluid pump 12 described herein can be used in various applications that can include, but are not limited to, fuel pumps, oil pumps, water pumps, combinations thereof, and other fluid pumps 12 that may be submerged or non-submerged.
It is contemplated that the PCB housing assembly 10 and terminals 90 can be incorporated within new pumps or can be manufactured for installation with after-market pumps.
Having described various aspects of the device, a method 400 is disclosed for operating the fluid pump 12. This method 400 includes step 402 of activating a pump element to draw a fluid 16 into a fluid path 26. The pump element operates to direct a fluid 16 to a position that defines a shadow port 60 (step 404). The fluid 16 is divided into a primary flow 54 of the fluid 16 toward an outlet 22 of the fluid path 26 and an excess flow 56 of the fluid 16 through an orifice of the shadow port 60 and into an accessory fluid path 30 (step 406). The excess flow 56 of the fluid 16 is directed to a thermistor 14 (step 408). A fluid temperature of the excess flow 56 of the fluid 16 in the accessory fluid path 30 is measured (step 410). The excess flow 56 of the fluid 16 is directed toward the inlet 20 of the fluid path 26 (step 412).
It is to be understood that variations and modifications can be made on the aforementioned structure without departing from the concepts of the present invention, and further it is to be understood that such concepts are intended to be covered by the following claims unless these claims by their language expressly state otherwise.
This application is a continuation of U.S. patent application Ser. No. 15/590,248, filed on May 9, 2017, entitled “THERMISTOR FLOW PATH,” which claims priority to and the benefit under 35 U.S.C. § 119(e) of U.S. Provisional Patent Application No. 62/342,615, filed on May 27, 2016, entitled “THERMISTOR FLOW PATH,” the entire disclosures of which are hereby incorporated herein by reference.
Number | Date | Country | |
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62342615 | May 2016 | US |
Number | Date | Country | |
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Parent | 15590248 | May 2017 | US |
Child | 16038614 | US |