The subject matter of this application relates to a pump.
In accordance with a first aspect of the subject matter disclosed herein there is provided a pump comprising a pump body defining an interior space having a first cavity and a second cavity, the first cavity having a cylindrical bounding surface and the second cavity having a bounding surface that includes a cylindrical portion, and the pump body also defining an inlet chamber and an outlet chamber positioned at least partially between the first and second cavities, an input passage opening into the inlet chamber, and an output passage opening from the outlet chamber, a first rotor member supported in the first cavity for rotating about a first rotational axis that coincides substantially with a central axis of the cylindrical bounding surface of the first cavity, the first rotor member having a cylindrical external surface and n vanes (n greater than one) projecting radially therefrom in equiangularly spaced relationship about the first axis, the vanes having tips lying on a cylindrical surface that is substantially equal in diameter to the cylindrical bounding surface of the first cavity, whereby during rotation of the first rotor member the tips of the vanes pass in effective sealing relationship with the bounding surface region of the first cavity, and wherein the cylindrical bounding surface of the first cavity extends at least 360/n degrees about said first axis, and a second rotor member supported in the second cavity for rotating about a second rotational axis that is parallel with the first rotational axis and coincides substantially with a central axis of the two cylindrical portions of the bounding surface of the second cavity, the second rotor member having a cylindrical external surface substantially equal in diameter to the cylindrical portion of the bounding surface of the second cavity, whereby during rotation of the second rotor member the cylindrical external surface of the second rotor member is in effective sealing relationship with the cylindrical portion of the bounding surface of the second cavity, and wherein the cylindrical external surface of the second rotor has n recesses therein in equiangularly spaced relationship about the second axis, wherein the first and second rotor members are disposed between the inlet chamber and the outlet chamber and the first and second rotor members are in effective sealing relationship with each other during rotation of the rotor members, the cylindrical portion of the bounding surface of the second cavity subtends an angle at the second axis at least as great as the angle subtended at the second axis by each recess in the cylindrical external surface of the second rotor member, and the pump further comprises a drive transmission mechanism coupled to the first and second rotor members for rotating the rotor members in opposite directions at equal angular velocities so that during a complete revolution of the first rotor member each vane successively emerges from a recess of the second rotor member, passes the inlet passage and the outlet passage, and enters a recess of the second rotor member, while the inlet chamber remains effectively sealed from the outlet chamber.
In accordance with a second aspect of the subject matter disclosed herein there is provided a pump comprising a pump body defining an interior space having a first cavity and a second cavity, the first cavity having a cylindrical bounding surface and the second cavity having a bounding surface that includes a cylindrical portion, and the pump body also defining an inlet chamber and an outlet chamber positioned at least partially between the first and second cavities, an input passage opening into the inlet chamber, and an output passage opening from the outlet chamber, a first rotor member supported in the first cavity for rotating about a first rotational axis that coincides substantially with a central axis of the cylindrical bounding surface of the first cavity, the first rotor member having a cylindrical external surface and n vanes (n greater than one) projecting radially therefrom in equiangularly spaced relationship about the first axis, the vanes having tips lying on a cylindrical surface that is substantially equal in diameter to the cylindrical bounding surface of the first cavity, whereby during rotation of the first rotor member the tips of the vanes pass in effective sealing relationship with the bounding surface region of the first cavity, and wherein the cylindrical bounding surface of the first cavity extends at least 360/n degrees about said first axis, and a second rotor member supported in the second cavity for rotating about a second rotational axis that is parallel with the first rotational axis and coincides substantially with a central axis of the two cylindrical portions of the bounding surface of the second cavity, the second rotor member having a cylindrical external surface substantially equal in diameter to the cylindrical portion of the bounding surface of the second cavity, whereby during rotation of the second rotor member the cylindrical external surface of the second rotor member is in effective sealing relationship with the cylindrical portion of the bounding surface of the second cavity, and wherein the cylindrical external surface of the second rotor has at least one recess therein, wherein the first and second rotor members are disposed between the inlet chamber and the outlet chamber and the first and second rotor members are in effective sealing relationship with each other during rotation of the rotor members, the cylindrical portion of the bounding surface of the second cavity subtends an angle at the second axis at least as great as the angle subtended at the second axis by said recess in the cylindrical external surface of the second rotor member, and the pump further comprises a drive transmission mechanism coupled to the first and second rotor members for rotating the rotor members in opposite directions at angular velocities such that during a complete revolution of the first rotor member each vane successively emerges from a recess of the second rotor member, passes the inlet passage and the outlet passage, and enters a recess of the second rotor member, while the inlet chamber remains effectively sealed from the outlet chamber.
For a better understanding of the invention, and to show how the same may be carried into effect, reference will now be made, by way of example, to the accompanying drawings, in which:
Referring to
The gear housing 18 is formed on the opposite side from the bearing recesses with a gear recess 46 (
An electric motor (not shown) having a drive shaft 58 is attached to the end cap 26. A drive pinion 62 is attached to the drive shaft of the motor and is in meshing engagement with the spur gear 50. Accordingly, when the motor drives the pinion 62, the two spur gears 50, 54 are driven at equal speeds in opposite directions.
The work rotor 38 is generally cylindrical and has two diametrically opposed vanes 66, 68 extending parallel to the central axis of the work rotor and projecting radially therefrom. When the work rotor rotates within the cavity 36 of the interior space, a small clearance exists between the tip of the vanes and the surface bounding the cavity 36. Thus, as the work rotor rotates, the work rotor and the pump rotor housing are in an effective sealing relationship. The cylindrical surface of the lower cavity extends at least 180 degrees about the central axis of the work rotor so that there is always at least one vane between the inlet passage and the outlet passage.
The pump rotor housing 14 is formed with an inlet passage 69 and an outlet passage 70 that communicate with the cavity 36. The upper end of each passage is internally threaded to receive a suitable hose attachment fitting.
The sealing rotor 42 is generally cylindrical and is formed with two peripheral notches 73, 74 that extend longitudinally of the rotor parallel to the axis of rotation of the rotor.
It will be appreciated from examination of
The radius of curvature of the upper cavity 37 in the regions Y is slightly greater than the radius of the cylindrical surface of the sealing rotor. The peripheral surface of the upper cavity in each of the regions Y subtends an angle at least as great as the angle subtended by the peripheral notches 73, 74, so that during rotation of the sealing rotor the external surface of the sealing rotor remains in effective sealing relationship with the pump rotor housing with respect to flow of gas around the sealing rotor.
The radius of curvature of the cavity 37 between the regions Y is somewhat greater than in the regions Y, which facilitates manufacture of the pump rotor housing because the tolerance on the dimensions of the peripheral surface of the upper cavity between the regions Y may then be greater than in the regions Y.
As shown in
Depending on the angular position of the work rotor 38, the sealing rotor 42 and the two vanes 66, 68 define two or three chambers within the cavity 36. At the position shown in
Referring again to
When the vane 66 reaches the lower edge of the inlet passage, the inlet chamber 71 that was bounded by the trailing flank of the vane 68 becomes a transfer chamber and a new inlet chamber 73 is created between the rotor seal and the trailing flank of the vane 66. The transfer chamber 71 between the leading flank of the vane 66 and the trailing flank of the vane 68 is isolated from the inlet passage. A quantity of gas is trapped in the transfer chamber, except for minor leakage between the tips of the vanes and the peripheral surface of the lower cavity 36. Advancing movement of the vane 66 pushes the trapped gas in the clockwise direction about the central axis of the working rotor.
As the work rotor continues to rotate, the tip of the vane 68 reaches the lower edge of the outlet passage 70. The outlet chamber and the transfer chamber are then in communication and a new outlet chamber is thereby created between the leading flank of the vane 66 and the rotor seal. The work rotor continues to rotate and the advancing of the vane 66 decreases the volume of the outlet chamber, tending to increase the pressure in the outlet chamber and expel gas from the outlet chamber through the outlet passage 40. The rotor seal and the narrow clearance between the peripheral surface of the upper cavity in the region Y and the cylindrical surface of the sealing rotor in the region Y provides a large resistance to leakage of gas from the outlet chamber. Accordingly, most gas is forced to leave the outlet chamber through the outlet passage.
The term effective sealing relationship used herein does not require a perfect seal, with the external surfaces of the work rotor and the sealing rotor, for example, continuously in sealing contact. An effective sealing relationship between two members requires that the rate at which fluid can leak between the members should be small relative to the rate at which fluid is delivered from the inlet passage to the outlet passage.
In a conventional external gear pump, the gear teeth divide the incoming flow of air into two streams, each of which is chopped by gear teeth into small volumes which are subsequently combined. This manner of operation consumes energy, resulting in heating of the gas. In the case of the pump illustrated in
In a modification of the pump shown in
It will be appreciated that the invention is not restricted to the particular embodiment that has been described, and that variations may be made therein without departing from the scope of the invention as defined in the appended claims, as interpreted in accordance with principles of prevailing law, including the doctrine of equivalents or any other principle that enlarges the enforceable scope of a claim beyond its literal scope. For example, the invention is not restricted to the sealing rotor having the same number of notches as the number of vanes of the work rotor. With suitable adjustments in timing of rotation of the rotors, the sealing rotor may have only one notch. Moreover, the work rotor may have more than two vanes, although it will be appreciated that as the number of vanes increases, the volume of the pump available for pumping fluid will decrease. Unless the context indicates otherwise, a reference in a claim to the number of instances of an element, be it a reference to one instance or more than one instance, requires at least the stated number of instances of the element but is not intended to exclude from the scope of the claim a structure or method having more instances of that element than stated. The word “comprise” or a derivative thereof, when used in a claim, is used in a nonexclusive sense that is not intended to exclude the presence of other elements or steps in a claimed structure or method.
This application claims benefit of U.S. Provisional Application No. 61/505,991 filed Jul. 8, 2011, the entire disclosure of which is hereby incorporated herein by reference for all purposes.
Number | Date | Country | |
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61505991 | Jul 2011 | US |