A modular symmetrical asphalt pumping system providing a series of field-configurable gear pumps and meters usable to safely and efficiently pump viscous molten fluids, such as, asphalt and similar bituminous materials. The system utilizes highly symmetrical physical geometries and modular component
A modular symmetrical asphalt pumping system providing a series of field-configurable gear pumps and meters usable to safely and efficiently pump viscous molten fluids, such as, asphalt and similar bituminous materials. The system utilizes highly symmetrical physical geometries and modular components to allow for the development of multiple pump configurations using a reduced quantity of parts. Preferred arrangements of the system reduce pump pulsing and cavitation.
대표청구항▼
1. A system, relating to providing user control of local geometries in pumping viscous molten fluids with a pump, through pump modularity, wherein the pump modularity permits placement variation among ports, passages, and driveshaft, comprising: a) a modular-component pump structured and arranged to
1. A system, relating to providing user control of local geometries in pumping viscous molten fluids with a pump, through pump modularity, wherein the pump modularity permits placement variation among ports, passages, and driveshaft, comprising: a) a modular-component pump structured and arranged to pump the viscous molten fluids;b) wherein said modular-component pump comprises i) a central pump housing having a first open end, a second open end, and an internal chamber extending between said first open end and said second open end,ii) an inlet to inlet the viscous molten fluids to said internal chamber and an outlet to outlet the viscous molten fluids from said internal chamber,iii) operating within said internal chamber, a shaft-driven fluid displacer structured and arranged to displace the viscous molten fluid from said inlet to said outlet,iv) a first single-geometry end unit structured and arranged to interchangeably engage a selected one of either of said first open end or said second open end,v) a second single-geometry end unit, having a geometric configuration common with said first single-geometry end unit, said second single-geometry end unit structured and arranged to interchangeably engage a remaining one of either of said first open end or said second open end, andvi) a set of interchangeable end-unit modifiers each one structured and arranged to interchangeably modify the function of said first single-geometry end unit and said second single-geometry end unit;c) wherein said shaft-driven fluid displacer comprises a driveshaft structured and arranged to operably couple said shaft-driven fluid displacer with a source of rotational power external of said central pump housing;d) wherein said set of interchangeable end-unit modifiers comprises i) a shaft-type modifier structured and arrange to modify either of said first single-geometry end unit and said second single-geometry end unit to comprise a drive-shaft passage enabling rotatable passage of said driveshaft, andii) cover-type modifiers, each one of the cover-type modifiers is structured and arrange to cover an external opening, of either of said first single-geometry end unit and said second single-geometry end unit, in fluid communication with an internal chamber; ande) wherein said modular-component pump assists to provide user control of local geometries in pumping the viscous molten fluids with said modular-component pump;f) wherein said shaft-driven fluid displacer is structured and arranged to generate, within said internal chamber, a suction-pressure region in fluid communication with said inlet and a discharge-pressure region in fluid communication with said outlet;g) wherein each one of said first single-geometry end unit and said second single-geometry end unit further comprise a first fluid return passage structured and arranged to return the viscous molten fluids from said discharge-pressure region to said suction-pressure region;h) wherein each said first fluid return passage comprises a first return inlet, a first return outlet, and a control valve structured and arranged to control passage of the viscous molten fluid between said first return inlet and said first return outlet;i) wherein each said control valve comprises a normally closed position blocking flow of the viscous molten fluids through said first fluid return passage and an open position enabling one-way flow of the viscous molten fluids between said first return inlet and said first return outlet;j) wherein each said control valve is configured to transition from said normally closed position to said open position in response to an elevated fluid pressure in said discharge-pressure region above a selected pressure threshold; andk) wherein when each said control valve is in said open position, return circulation of the viscous molten fluids through said first fluid return passage is enabled between said discharge-pressure region and said suction-pressure region. 2. The system according to claim 1 wherein each said control valve comprises a pressure-threshold selector structured and arranged to enable user selection of the selected pressure threshold. 3. The system according to claim 2 wherein: a) said modular component pump is a positive-displacement external gear pump;b) said shaft-driven fluid displacer comprises i) a first pumping gear disposed rotatably within said internal chamber, andii) meshing with said first pumping gear, a second pumping gear disposed rotatably within said internal chamber;c) said first pumping gear comprises i) said drive shaft, andii) a first rotational axis oriented coaxially with said drive shaft;d) said second pumping gear comprises a second rotational axis spaced apart from and generally parallel to said first rotational axis;e) each said first single-geometry end unit and said second single-geometry end unit comprises gear-journal bores structured and arranged to rotatably journal therein said first pumping gear and said second pumping gear;f) each one of said gear-journal bores is structured and arranged to interchangeably journal therein either one of said first pumping gear and said second pumping gear; andg) each one of said gear-journal bores extends through one of said single-geometry end units to enable passage of said driveshaft through one of said single-geometry end units. 4. The system according to claim 3 wherein: a) when disposed within said internal chamber, said first pumping gear and said second pumping gear are structured and arranged to divide said internal chamber into a first chamber portion and a second chamber portion;b) said first chamber portion is configured to comprise said suction-pressure region when said driveshaft is driven in a forward rotation;c) said second chamber portion is configured to comprise said discharge-pressure region when said driveshaft is driven in the forward rotation;d) said first chamber portion is configured to comprise said discharge-pressure region when said at least one driveshaft is driven in a reversed rotation;e) said second chamber portion is configured to comprise said suction-pressure region when said driveshaft is driven in the reversed rotation; andf) each said first fluid return passage is in fluid communication with both said first chamber portion and said second chamber portion. 5. The system according to claim 4 wherein said first single-geometry end unit and said second single-geometry end unit each comprise: a) a first plane of symmetry dividing said single-geometry end unit into a first half portion and a second half portion;b) wherein said first half portion and said second half portion comprise symmetrically opposite functional geometries;c) wherein, said first plane of symmetry is located equidistant from both said first rotational axis and said second rotational axis; andd) wherein, when said first single-geometry end unit and said second single-geometry end unit are each mated to said central pump housing, said first plane of symmetry is oriented about perpendicular to an axis-containing plane containing both said first rotational axis and said second rotational axis. 6. The system according to claim 5 wherein: a) each said first half portion and each said second half portion each comprise a gear-journal bore of said gear-journal bores; andb) each one of said gear-journal bores includes a bearing. 7. The system according to claim 6 wherein each said bearing is a plain bearing. 8. The system according to claim 6 wherein each said bearing is a rolling-element bearing. 9. The system according to claim 5 wherein: a) each said first fluid return passage is disposed between said gear-journal bores and in one position intersects said first plane of symmetry; andb) said first single-geometry end unit and said second single-geometry end unit are structured and arranged to be symmetrically mountable to said central housing to selectably locate each said first return inlet and each said first return outlet in fluid communication with either of said first chamber portion and said second chamber portion. 10. The system according to claim 9 wherein said central housing further comprises: a) a mount structured and arranged to assist mounting of said modular-component pump to a mountable support external of said modular-component pump;b) wherein said mount comprises a mounting contact surface, comprising a contact-surface plane, structured and arrange to contact the mountable support;c) wherein said central housing is further structured and arranged to orient said axis-containing plane, containing both said first rotational axis and said second rotational axis, in a non-parallel orientation relative to said contact-surface plane; andd) wherein said non-parallel orientation geometrically positions one of said first rotational axis and said second rotational axis further from said mounting-surface plane than the other one of said first rotational axis and said second rotational axis when said first pumping gear and said second pumping gear are journaled rotatably within said first single-geometry end unit and said second single-geometry end unit. 11. The system according to claim 10 wherein said central housing is further structured and arranged to orient said axis-containing plane, containing both said first rotational axis and said second rotational axis, at about a 45-degree angle relative to said contact-surface plane. 12. The system according to claim 10 wherein said shaft-type modifier comprises: a) detachably mountable to either of said first half portion and said second half portion, an apertured cap plate having a shaft-passing aperture structured and arranged to enable outward passage of said driveshaft therethrough;b) wherein said shaft-passing aperture of said apertured cap plate is structured and arranged to coaxially align with a respective one of said gear-journal bores when said apertured cap plate is detachably mounted to either of said first half portion and said second half portion. 13. The system according to claim 12 wherein each one of said cover-type modifiers comprises: a) detachably mountable to either of said first half portion and said second half portion, a non-apertured cap plate structured and arranged to cover a respective one of said gear-journal bores when said apertured cap plate is detachably mounted to either of said first half portion and said second half portion. 14. The system according to claim 10 wherein one of said first single-geometry end unit and said second single-geometry end unit comprises a first outer fluid jacket structured and arranged to assist circulation of a thermal-transfer fluid usable to control the temperature of the viscous molten fluids within said first single-geometry end unit and said second single-geometry end unit. 15. The system according to claim 10 wherein said central pump housing comprises a second outer fluid jacket structured and arranged to assist circulation of the thermal-transfer fluid usable to control the temperature of the viscous molten fluids within said central pump housing. 16. The system according to claim 13 wherein: a) said first single-geometry end unit is operably-mounted to said central pump housing in an orientation locating said first return inlet, of said first single-geometry end unit, in fluid communication with said second chamber portion;b) said second single-geometry end unit is operably-mounted to said central pump housing in an orientation locating said first return inlet, of said second single-geometry end unit, in fluid communication with said first chamber portion;c) return circulation of the viscous molten fluids is enabled between said second chamber portion and said first chamber portion through said first fluid return passage of said first single-geometry end unit when a fluid pressure above the selected pressure threshold is developed within said discharge-pressure region of said second chamber portion by a forward rotation of said input shaft; andd) return circulation of the viscous molten fluids is enabled between said first chamber portion and said second chamber portion through said first fluid return passage of said second single-geometry end unit when a fluid pressure above the selected pressure threshold is developed within said discharge-pressure region of said first chamber portion by a reverse rotation of said input shaft. 17. The system according to claim 16 wherein said pressure-threshold selector of said control valve of said first single-geometry end unit is adjustable independently of said pressure-threshold selector of said control valve of said second single-geometry end unit. 18. The system according to claim 13 wherein: a) said first single-geometry end unit is operably-mounted in an orientation locating said first return inlet, of said first single-geometry end unit, in fluid communication with said second chamber portion;b) said second single-geometry end unit is operably-mounted in an orientation locating said first return inlet, of said second single-geometry end unit, in fluid communication with said second chamber portion; andc) high-volume return circulation of the viscous molten fluids is enabled between said second chamber portion and said first chamber portion by a return flow through both said fluid return passages of said first single-geometry end unit and said second single-geometry end unit when a fluid pressure above the selected pressure threshold is developed within said discharge-pressure region of said second chamber portion. 19. The system according to claim 6 further comprising: a) a second fluid return passage structured and arranged to return the viscous molten fluids from said discharge-pressure region to said suction-pressure region;b) wherein said second fluid return passage comprises i) in fluid communication with said discharge-pressure region, a second return inlet,ii) in fluid communication with said suction-pressure region, a second return outlet, andiii) in fluid communication with said second return inlet and said second return outlet, a fluid pathway passing through one of said gear-journal bores. 20. The system according to claim 19 wherein: a) said fluid pathway extends between a shaft journal of said shaft-driven fluid displacer and a plain bearing of the one of said gear-journal bores; andb) passage of the viscous molten fluids through said fluid pathway assists friction-reducing lubrication of said plain bearing. 21. The system according to claim 20 wherein said second fluid return passage is part of a flow modulator structured and arranged to modulate the flow volume of the viscous molten fluids through said fluid pathway. 22. The system according to claim 21 wherein each one of said first pumping gear and said second pumping gear comprises: a) a set of gear teeth defining an outer addendum circle and an inner root circle; andb) an opposing pair of terminating gear faces defining a gear-face width;c) wherein each terminating gear face of said opposing pair of terminating gear faces is oriented transversely to a respective rotation axis of said first pumping gear and said second pumping gear. 23. The system according to claim 22 wherein each one of said first single-geometry end unit and said second single-geometry end unit comprises: a) an inner chamber face structured and arranged to be in communication with said internal chamber;b) wherein said inner chamber face is located adjacent to and in parallel orientation with said terminating gear faces. 24. The system according to claim 23 wherein said second return inlet comprises: a) located within said inner chamber face, an inlet channel structured and arranged to assist channeling of the viscous molten fluids from said discharge-pressure region to said gear-journal bore of said gear-journal bores;b) wherein said inlet channel is located within a region of said inner chamber face adjacent to one of said terminating gear faces; andc) wherein a portion of said inlet channel is located within a region of said inner chamber face located within about the outer addendum circle of said terminating gear face. 25. The system according to claim 24 wherein said second return outlet comprises: a) located within said inner chamber face, an outlet port structured and arranged to outlet the viscous molten fluids from said fluid pathway to said suction-pressure region;b) wherein said outlet port is located within a region of said inner chamber face adjacent to one of said terminating gear faces. 26. The system according to claim 25 further comprising metering device structured and arranged to meter outputs of the viscous molten fluids. 27. The system according to claim 26 wherein said metering device comprises a coriolis-type flow meter. 28. A pumping system relating to pumping viscous molten fluids comprising: a) a modular-component pump structured and arranged to pump the viscous molten fluids;b) wherein said modular-component pump comprises i) a pump housing having a right-hand open end, a left-hand open end, and an internal chamber extending between said right-hand open end and said left-hand open end,ii) an inlet to inlet the viscous molten fluids to within said internal chamber and an outlet to outlet the viscous molten fluids from said internal chamber,iii) operating within said internal chamber, a shaft-driven fluid displacer structured and arranged to displace the viscous molten fluid from said inlet to said outlet, andiv) mounted to each of said right-hand open end and said left-hand open end, a modifiable single-geometry end unit structured and arranged to modifiably cover said internal chamber;v) wherein said shaft-driven fluid displacer comprises a driveshaft structured and arranged to operably couple said shaft-driven fluid displacer with a source of rotational power external of said pump housing;c) wherein said modular-component pump is configurable in four configurations using the modifiable single-geometry end units;d) wherein said modifiable single-geometry end units are selectably mountable to said pump housing in said four configurations;e) wherein two left-hand driveshaft configurations, enabling left-hand outward passage of said driveshaft from said pump housing, are field configurable; andf) wherein two right-hand driveshaft configurations, enabling right-hand outward passage of said driveshaft from said pump housing, are field configurableg) wherein each said modifiable single-geometry end unit comprises a pressure-relief valve structured and arranged to return circulation of the viscous molten fluids between said discharge-pressure region and said suction-pressure region of said internal chamber in response to an elevated fluid pressure in said discharge-pressure region above a selected pressure threshold; andh) wherein said modular-component pump is field configurable in three pressure-relieving configurations using two modifiable single-geometry end units. 29. A pumping system relating to pumping viscous molten fluids comprising: a) a modular-component pump structured and arranged to pump the viscous molten fluids;b) wherein said modular-component pump comprises i) a pump housing having a first open end, a second open end, and an internal chamber extending therebetween,ii) an inlet to inlet the viscous molten fluids to within said internal chamber and an outlet to outlet the viscous molten fluids therefrom,iii) operating within said internal chamber, a shaft-driven fluid displacer structured and arranged to displace the viscous molten fluid from said inlet to said outlet, andiv) a modular housing plate mountable to either of said first open end and said second open end;c) wherein said shaft-driven fluid displacer comprises a driveshaft structured and arranged to operably couple said shaft-driven fluid displacer with a source of rotational power external of said central pump housing;d) wherein said modular housing plate is configurable as either a pump end plate, to cap a selected one of either said first open end or said second open end, or a pump shaft plate structured and arranged to accommodate passage of said driveshaft through said modular housing plate from a selected one of either of said first open end or said second open end;e) wherein when disposed within said internal chamber, said shaft-driven fluid displacer divides said internal chamber into a high pressure region and a low pressure region;f) wherein said modular housing plate comprises a pressure-relief valve structured and arranged to return circulation of the viscous molten fluids between said high pressure region and said low pressure region of said internal chamber in response to an elevated fluid pressure in said high pressure region above a selected pressure threshold; andg) wherein said modular-component pump is field configurable in three pressure-relieving configurations using two modular housing plates. 30. A pump system, comprising: a) a gear pump the gear pump includes an internal pumping chamber;b) disposed within said internal pumping chamber, a set of intermeshing helical gears;c) wherein each helical gear of said set of intermeshing helical gears comprises i) a set of gear teeth defining an outer addendum circle and an inner root circle; andii) an opposing pair of terminating gear faces defining a gear-face width;d) wherein each terminating gear face of said opposing pair of terminating gear faces is oriented transversely to a respective rotation axis of said set of intermeshing helical gears;e) wherein said set of gear teeth comprise a helix angle, relative to said respective rotation axis, providing exactly a one-half tooth pitch rotation from one terminating gear face to the opposing terminating gear face, said set of gear teeth are structured and arranged to reduce fluid pressure pulses relative to a set of gear teeth with straight teeth by pulse pressure cancellation;f) wherein when disposed within said internal chamber, said set of intermeshing helical gears are structured and arranged to divide said internal chamber into a discharge-pressure region and a suction-pressure region;g) wherein said gear pump includes a fluid return passage structured and arranged to return the viscous molten fluids from said discharge-pressure region to said suction-pressure region;h) wherein said fluid return passage includes: i) in fluid communication with said discharge-pressure region, a return inlet,ii) in fluid communication said suction-pressure region, a return outlet, andiii) in fluid communication with said return inlet and said return outlet, a fluid pathway extending therebetween;i) wherein said fluid return passage forms a flow modulator to modulate the flow volume of the viscous molten fluids through said second fluid pathway;j) said set of intermeshing helical gears are structured and arranged to control operation of said flow modulator and to coordinate the operational timing of said flow modulator with cyclic pressure fluctuation exhibited by said gear pump during operation. 31. The system according to claim 30 further comprising metering device structured and arranged to meter outputs of the viscous molten fluids.
연구과제 타임라인
LOADING...
LOADING...
LOADING...
LOADING...
LOADING...
이 특허에 인용된 특허 (21)
Way Donald R. (Scottsdale AZ), Adjustable gear pump.
Byerly David J. (Lawrenceville GA) Frates Paul S. (Lawrenceville GA) Scholl Charles H. (Duluth GA), Apparatus for melting and dispensing thermoplastic material.
※ AI-Helper는 부적절한 답변을 할 수 있습니다.