Pumps – Expansible chamber type – Elongated flexible chamber wall progressively deformed
Reexamination Certificate
2000-03-01
2001-10-02
Freay, Charles G (Department: 3746)
Pumps
Expansible chamber type
Elongated flexible chamber wall progressively deformed
C477S040000, C092S071000
Reexamination Certificate
active
06296460
ABSTRACT:
FIELD OF THE INVENTION
This invention relates generally to fluid pumps and particularly to those capable of precision small volume fluid metering delivery.
BACKGROUND OF THE INVENTION
Pumps comprise one of the most common and well developed as well as well known types of basic machines. The essential function of a pump is the displacement and movement or pressurization of a fluid. The majority of pumps may be divided into a basic classification as either reciprocating or rotary action pumps. Reciprocating pumps typically utilize one or more cylinders together with appropriate valves for controlling fluid flow to and from the cylinders. Each cylinder is fitted with a moving piston which in turn is usually coupled to crank mechanism for imparting piston movement within the cylinder in response to rotation of an input power or drive shaft.
In contrast, rotary pumps may be generally characterized as apparatus having a shaft coupled to a source of rotary power which is supported within a pump body. The latter, defines a chamber or cavity within which a fluid movement or displacement device is rotated by the input power shaft. Perhaps the most pervasive type of rotary pump may be generally described as an impeller type pump. In such pumps, a rotor is positioned within the pump chamber and rotated by the input power shaft. The rotor in turn supports a plurality of blades which are sized and configured in general correspondence with the interior chamber of the pump housing. An input port and an output port are formed in the pump housing in communication with the chamber. As the input drive shaft rotates the rotor and its plurality of impeller blades within the pump chamber, the fluid is drawn into the chamber through the input port and forced outwardly through the output port.
Another type of rotary pump is typically referred to as a turban or vane type pump. The turban or vane pump utilizes a housing defining a chamber which is usually cylindrical in shape which supports a plurality of static vanes radially disposed within the chamber interior. An armature is rotatably supported within the pump chamber and further supports a plurality of rotating vanes which are moveable with respect to the static vanes. A drive shaft is coupled to a source of operative rotary power and is further coupled to the armature. As rotary power is applied to the armature, the interaction of the rotating vanes and static vanes produces a turban-like displacement of the fluid within the chamber. Typically an input port is coupled to one end of the chamber while an output port is coupled to the downstream end of the pump chamber.
Still another type of rotary action pump is referred to generally as a “peristaltic” which is often referred to as a “hose pump”. Peristaltic pumps utilize a housing within which a generally cylindrical chamber is formed. A flexible tubing or hose is positioned against the outer surface of the housing chamber. One end of the tubing or hose is coupled to an input fluid supply while the remaining end forms an output port for the pump. A rotor is rotatably supported within the chamber and further supports one or more rollers about its periphery. The rollers are positioned against the flexible tubing or hose and are of sufficient size to deform the hose to provide pinching or closure at the point of roller pressure. A drive shaft is coupled to the rotor and to a source of rotational power. As the rotor rotates, the rollers displace quantities of fluid in the direction of rotor rotation to transfer the fluid from the input source to the output port.
While most pumps are used in applications which require the pumps to simply run for relatively long periods at a so-called steady state, in certain environments pumps must also be capable of providing short term small volume runs to transfer fluid in more precise quantities. Such pumps are often referred to as “fluid metering” pumps and are characterized by precise volume delivery of fluid. In many instances, such fluid metering pumps are used in an operative environment in which the rotating member is moved through small angular displacements substantially less than a full rotation.
While the above described prior art pumps have been the subject of substantial refinement and development, they have yet to provide pumps which are capable of both steady state operation and fluid metering operation. Many of the above described prior art pumps have been subject to an undesirable tendency to impart a pulsating characteristic to the fluid flow. There remains therefore a continuing need in the art for an improved rotary drive pump which is capable of providing smooth pulse free fluid flow as well as accurate fluid metering operation.
SUMMARY OF THE INVENTION
Accordingly, it is a general object of the present invention to provide an improved rotary cavity pump. It is a more particular object of the present invention to provide an improved rotary cavity pump which is capable of providing extremely precise fluid metering operation through partial pump revolution as well as relatively pulse-free fluid flow during more conventional pump action.
In accordance with the present invention there is provided a rotary cavity pump for pumping a fluid, the pump comprising: a pump housing having a plurality of pump cavities each defining a pump recess and first and second apertures in the recess; a plurality of diaphragms sealingly supported upon the plurality of pump cavities each of the diaphragms being formed of a flexible resilient material having a relaxed shape which together with the pump recesses forms a sealed fluid cavity having the first and second apertures therein; a first fluid coupling and means for coupling the first fluid coupling to the first apertures; a second fluid coupling and means for coupling the second fluid coupling to the second apertures; a plurality of diaphragm compression members; and means for moving the plurality of diaphragm compression members upon and across the diaphragms, the diaphragms being compressed into the recesses to block the first apertures and captivate a quantity of fluid and to expel the quantity outwardly through the second apertures.
In one anticipated embodiment of the present invention, a rotary cavity pump for pumping a fluid comprises, a transfer plate having a plurality of arcuate pump cavities each defining an arcuate recess, a first aperture and first passage at one end of the recess and a second aperture and second passage at the remaining end of the recess; a manifold coupled to the transfer plate having a first fluid port coupled to each of the first passages and a second fluid port coupled to each of the second passages; a plurality of resilient diaphragms each sealingly supported upon one of the pump cavities; and a compression plate rotatably supported with respect to the diaphragms and having a plurality of compression members, the compression members compressing the diaphragms as the compression plate rotates to isolate fluid within the recesses and expel it through the second apertures and the second passages.
In still another respect, the present invention provides a rotary cavity pump for use with a fluid, said pump comprising: a pump housing; a compression plate rotatably supported on the pump housing and having a plurality of compression members; a plurality of deformable pump segments supported by the pump housing against the compression members, each of the deformable pump segments including, an elongated pump cavity having an elongated recess having apertures at each end thereof, and a resilient diaphragm covering the pump cavity, the resilient diaphragm deforming and reforming as a compression member is moved upon it to draw fluid into the recess through one of the apertures and expel fluid out from the recess through the remaining one of the apertures.
REFERENCES:
patent: 612834 (1898-10-01), Dieckmann
patent: 2841091 (1958-07-01), Schaurte
patent: 3922119 (1975-11-01), Rosenquist
patent: 5676035 (1997-10-01), Chrestoff et al.
Ekstrand Roy A.
Freay Charles G
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