This application relates to a vane pump, wherein a pump fluid inlet window has a unique shape.
Vane pumps are known, and typically include a rotor carrying a plurality of radially movable vanes. The vanes are urged outwardly into contact with a cam surface. The cam surface may be formed within a liner, which is mounted within an outer housing.
The rotor is mounted eccentrically within the cam surface, such that the size of pump chambers increase, and then decrease as the rotor moves from an inlet portion of a cycle toward a discharge portion. While the pump is moving through the inlet portion, fluid moves in through an inlet window, and the fluid is then discharged through an outlet window after the pump cycle is completed.
There are stresses and forces on the vanes and the cam surface from the interacting movement and pressure differentials across the pump. There are particular high contact stresses formed on the cam surface at areas associated with the inlet window, and in particular at downstream ends of the inlet window.
A vane pump has an inlet window and a discharge window formed within a cam surface. The vane pump includes a rotor carrying a plurality of radially extending vanes which are biased into contact with the cam surface. The rotor has a direction of rotation such that one end of the inlet window can be described as an upstream end, and an opposed end as a downstream end. The inlet window extends for a relatively long width along a rotational axis of the rotor at the upstream end. Angularly extending sides reduce an axial width of the inlet window in a direction moving in a downstream direction from the upstream end.
These and other features of the present invention can be best understood from the following specification and drawings, the following of which is a brief description.
A pump 20 is illustrated in
Pump chambers 24 are formed between the cam surface 26, and adjacent ones of the vanes 23. While not shown, the vanes 23 can move radially inwardly and outwardly of the rotor 22. The rotor 22 is mounted eccentrically within the liner 25, and driven to rotate such that the size of the pump chambers 24 increase as it moves through an inlet portion of a pump cycle, and over the inlet window 28, and then begin to decrease as it moves toward a discharge portion.
As shown in
In one embodiment, the angled portions 38 extend at an angle A of about 11.2°. The radius R1 is 0.250″ (6.35 mm), and the radius R2 is 0.125″ (3.17 mm). However, any number of other shapes and dimensions may come within the scope of this invention.
This window shape, by reducing the width of the inlet window 28 at locations moving in a downstream direction, reduces the contact stress concentration on the relatively thin sides of the liner 25 on opposed axial ends of the inlet window 28.
For purposes of complete description, the angles A, B, and C are measured to be the angle at which the sides extend axially inwardly to reduce the width of the inlet window 28, 128 in a direction moving downstream, and measured from a plane extending parallel to an axis of rotation of the rotor 22, and in particular the plane defining the straight sides 36, 136.
Although embodiments of this invention have been disclosed, a worker of ordinary skill in this art would recognize that certain modifications would come within the scope of this invention. For that reason, the following claims should be studied to determine the true scope and content of this invention.