US2527915A

US2527915A - Fluid motor for deep well pumps

Info

Publication number: US2527915A
Application number: US754294A
Authority: US
Inventors: Glenn A Cherry; William D Hankey
Original assignee: Individual
Current assignee: Individual
Priority date: 1947-06-12
Filing date: 1947-06-12
Publication date: 1950-10-31
Anticipated expiration: 1967-10-31

Description

Oct. 31, 1950 G, A, CHERRY ErAL 2,527,915

FLUID MOTOR FOR DEEP WELL PUMPS Filed June l2, 1947 2 Sheets-Sheet l FIG.

Eyfjw Oct. 31, 1950 G. A. CHERRY ETAL 2,527,915

v FLUID MoToR FOR DEEP WELL PUMES L Filed June l2, 1947 2 Sheets-Sheet 2:

GL E/v/v A. CHERRY W.. D. HAN/(EY INVENTORS Patented 3l, 1950 UNI-'rizo FLUID MOTOR FOR DEEP WELL PUIVIPS GlennA. Cherry and William D. Hankey Butler, Ind. v

Appiicatin June'iz, 1947, serial Na. 754,294

4 claims. (ci. 121-150) reciprocating piston type and, more particularly,

to a fluid motor combined and cooperating with a fluid driven control valve.

Heretofore, fluid motors have been widely used for the operation of well pumps. Generally, the action of the pistons in such fluid motors has been in one direction, upward; gravity and the weight of the piston and its connecting rods have been relied upon to reposition the piston for each stroke. In addition, fluid motors have been exceedingly complex in construction and, therefore, costly to maintain.

One of the objects of the present invention is to provide a fluid motor of the reciprocating piston type combined with a iiuid operated control valve, the iiuidmotor having a piston which is positively acted upon and driven alternately in each direction.

Another object is to provide a fluid motor of the reciprocating piston type combined with a. fluid operated control valve of simple and in expensive construction.

A further object is to provide a fluid motor of the type described, eflicient in operation andof relatively few working parts. i

' With these and other objects in view, which may be incident to our improvements, the invention consists in the parts and combinations to be hereinafter set forth and claimed, with the understanding that the several necessary elements, comprising dur invention may be varied in construction, proportions and arrangements, without departing from the spirit and scope of the appended claims.

In order to make our invention more clearly understood, We have shown in the accompanying drawing means for carrying the same into practical effect, without limiting the improvements in their useful applications to the particular constructions, which for the purpose of explanation, have been made the subject of illustration.

In the drawings:

Figure 1 is a plan view of the fluid motor and its control valve; 'f

Fig. 2 is a sectional view along line 2--2 of Fig-1:

Fig. 3 is a sectional view along'line 3-3 of Fig. 1;

Fig. 4, is a sectional view along line 4-4 of Figs. 2 and 3; and

Fig. 5 is a sectional view along line 5-5 of Fig. 1.

Referring to the drawings, and more particularly to Fig. 1, there is shown a valve chamber housing I0, having a valve chamber- I'I, within which a hollow control valve I2 reciprocates. The valve chamber housing I0 has at one end a block I3 containing an outlet port I4, hereinafter described in detail, and at the other end a housing member I5 for a driving piston, designated generally by numeral I6, attached to the valve I2. Valve driving piston I6 is attached at I8 to control valve I2 by means of a connecting rod I1. The main inlet port I9 enters the valve chamber housing I0 at 20a; branchingl from this inlet port I9, prior to its entrance to the valve chamber II, is a passage 20, connected tothe main piston chamber 2l as shown in Figs. 1 and 3. Parallel to the valve chamber II is an outlet passage 22, connected at one end to outlet port I4, the opposite end portion of the passage being connected

toports

23 and 24, which open into the chamber of the valve driving piston I6.

Referring to Fig. 2, the valve chamber housing I0, the reciprocating control valve I2, and the housing I5 which contains the valve piston I6 to drive the control valve I2 are shown in greater detail. It will be noted that the control valve I2 has cut-out portions 25 and 26, and that the circumferentially notched

portions

21 and 28 are in sliding contact with the walls of valve chamber. It will also be noted that the valve piston head I6 comprises opposed cup-shaped resilient discs 29 attached to the valve connecting rod I1 at I8 by any suitable means, the discs being constructed and arranged so that they are urged outwardly into contact with the inner walls of the housing I5.

The main piston 30 (Figs. 2 and 3) reciprocates within the main piston chamber 2 I. The housing 3| which contains the piston chamber and piston is provided with

passages

20, 32, and 33; passage 20 leads from points midway the length of the piston chamber 2l to main inlet port I9 (Fig. 1) passage 32 connects the valve chamber II to the piston chamber 2| at a point below the pistony 30; passage 33 connects the valve piston chamber I5 to the main piston chamber 2I at a point in the same horizontal plane with the lower port of entry of passage 20. The main piston 30 is provided with circumferential grooves 34 and 35, the grooves being positioned in such manner that they are adapted to coact with passages between the main piston chamber and the valve control unit.

Referring to Fig. 3, which is the reverse of Fig. 2, lmet port I9 and passage 20 are shown by dotted lines. Passage 20, as explained above, connects points midway the length ofthe main picton 3 chamber 2| to the inlet port I6; this passage is provided with two inlet ports 66 and 31, arranged in spaced vertical relationship, Drt 36 being adapted to register with groove 34 when the piston 36 is in the lowermost position of its stroke and port 31 being adapted to register with groove 36 when the piston 36 is at the peak of its stroke.

The valve piston housing I is connected to the main piston chamber 2I by means of a tube 36. provided with suitable fittings 33 and 25a. It will be noted that tube 36 is connected to the main piston chamber at a point in the piane of the inlet 36 (Fig. 3). Valve chamber II is also connected directly to piston chamber 2i by means of passage 46, adapted to coact with cut-out portions and 26 of the control valve I2. The control valve I2 is formed with a passage 42 lengthwise thereof, said passage opening into the exhaust port I4, and into the cut-out portion 26 through an opening 4I (Fig. 2).

The disposition of the passages around the piston and valve chambers, respectively is shown in Figs. 4 and 5. It will be noted in Fig. 5 that an adjustable set screw 43 is provided whereby the outlet from the piston housing I5 may be restricted to passage 22. A similar set screw 44 is provided for outlet 24 (Fig. l)

As will be seen in Figs. 2 and 3, the main piston 36 is suitably connected as at 45 to a. pumping mechanism (not shown) by means of rod 46. It is readily apparent that when main piston reciprocates within its chamber 2i, rod 46 is positively driven alternately up and down.

The operation of the above-described uid pump and its control valve is simple and effective. Hydraulic fluid, preferably oil, is forced into the pump under pressure by any conventional means, ior example, an electric motor and an oil pump, not shown. With the control valve I2 in the position shown, in Figs. 2 and 3, fluid under pressure enters port i9 into the cutout portion 26 of valve I2, through passage 32, and into the cavity beneath main piston 30 within piston chamber 2|, forcing piston 36 upwardly until groove in the piston registers with passage 33. Fluid entering port I9 also enters passage 2D, which branches off from entry I9, and flows to inlet port 31 in the main piston chamber 2I. When main piston 30 has been driven upwardly, the full extent of its stroke, groove 35 is aligned with inlet port 31 and passage 33. Fluid entering port 31 flows around groove 35 in piston 36, out through passage 33, and upwardly into the valve piston housing I5, where it acts upon the inner face of valve piston head I6. Under this pressure, control valve I2 is forced to a position opposite from that shown in Figs. 2 and 3. When the control valve I2 is forced to its new position, that is to say, when piston I6 has reached the outer limit of its travel in housing I5, fluid entering port I9, passes into cutout portion 26 of the control valve I2 and into passage 46, which is directly connected tothe cavity above the main piston 30 in the piston chamber 2I, thus forcing the main piston downwardly. Upon downward movement of the main piston 30, the fluid therebelow, which was utilized to raise the piston, is forced out of the chamber 2 I, back through passage 32, into valve chamber il and out through I4 into a storage or supply tank, not shown. When the piston 30 reaches its full stroke downward, groove 34 registers with port 36 and passage 41 which leads to the tube 66. Fluid entering passage 20 now proceeds around groove 34, through tube 3l. and into valve lthe piston is caused piston housing Il, where it acta upon valve piston I6, forcing the control shown in Figs. 2 and 3.

Referring to Fig. 1, the iluid used to force valve piston I6 from its initial positionas shown in Figs. 2 and 3, escapes through restricted port 24 into passage 22 and out through port I4, when the valve piston returns to its original position. It will be understood that fluid which has forced piston I6 to. its initial position escapes through restricted port 23 into passage 22 and out through port Il, when the valve piston reverses. Fluid which has forced the main piston 30 downward must escape when the piston starts its upward stroke; this fluid, no longer under pressure as the piston starts upward. since pressure is now directed to the bottom of piston. escapes through passage 46, into cutout portion 25 of control valve I2, through outlet 4I, in the control valve. through passage 42, and out through port I4 to the oil supply tank.

It will thus be seen that main piston 36 is forced up and down by iiuid pressure which is directed alternately to either end of said piston by the reciprocating action of control valve I2. When to reciprocate positively in this manner, it is apparent that rod 46 moves effectively up and down, which movement may be utilized to operate a well pump or any other mechanism. This pumping head is designed to operate directly over a well with the power unit located at any convenient place, preferably in a dry shelter, that affords protection to the power unit.

While we have shown and described the preferred embodiment of our invention, we wish it to be understood that We do not contlne ourselves to the precise details of construction herein set forth, by way of illustration, as it is apparent that many changes and variations may be made therein, by those skilled in the art, without departing from the spirit of the invention or exceeding the scope of the appended claims.

We claim:

l. A fluid motor of the character described, comprising a piston chamber having a freely movable piston therein, a housing having a control valve chamber and a chamber for a piston to actuate a control valve, a control valve slidably mounted in said valve chamber and a piston slidably mounted in said piston chamber, a connecting rod between the piston and the valve whereby the valve and piston move as a unit, the chamber for the control valve actuating piston having a pair of uid inlet ports and a pair of outlet ports, one inlet port and one outlet port of each pair being connected to opposite ends of the chamber, means to connect said fluid pressure inlet ports to the chamber of the freely movable piston at points intermediate the ends thereof, the control valve chamber having a fluid pressure inlet port, a pair of outlet ports and an exhaust port, means to connect said fluid pressure inlet port at points intermediate of the ends of the chamber of the freely movable piston, a, pair of iluid passages connecting the outlet ports of the control valve chamber with opposite ends of said chamber of the freely movable piston, said passages serving as inlet and exhaust lines for iluid from the control valve chamber to the chamber of the freely movable piston and from said chamber to the exhaust port of the control valve chamber, means formed on the freely movable piston adapted to alternately ccact with the iluid pressure inlet ports of its chamber and valve I2 to the position the passages from said chamber to the valve piston chamber, whereby to introduce liquid under pressure at alternate ends of the chamber of the freely movable piston and reciprocate the piston therein.

2. A fluid motor of the character described, comprising a piston chamber having a freely movable piston therein, a housing rpositioned at 90 to the axis of the piston chamber, said housing have a control valve chamber and a chamber for a piston to actuate a control valve, a control valve slidably mounted in said valve chamber and a piston slidably mounted in said piston chamber, a connecting rod between the piston and the valve whereby the valve and piston move as a unit, the chamber for the control valve actuating piston having a pair of fluid inlet ports and a pair of outlet ports, one inlet port and one outlet port of each pair being connected to opposite ends of the chamber, means to connect said fluid pressure inlet ports to the chamber of the freely movable piston at points intermediate the ends thereof, the control valve chamber having a fluid pressure inlet port, a pair of outlet ports and an exhaust port, means to connect said fluid pressure inlet port at points intermediate of the ends of the chamber of the freely movable piston, a pair of fluid passages connecting the outlet ports ofthe control valve chamber with opposite ends of the chamber of the freely movable piston, said passages serving as inlet and exhaust lines for fluid from the control valve chamber to the chamber of the freely movable piston and from said chamber to the exhaust port of the control valve chamber, means formed on the freely movable piston comprising a circumferential groove in the vicinity of each end of the piston adapted to alternately coact with the uid pressure inlet ports of its chamber and the passages from said chamber to the valve piston chamber, whereby to introduce liquid under pressure at alternate ends of the chamber of the freely movable'piston and reciprocate the piston therein.

3. A fluid motor of the character described, comprising a piston chamber having a freely movable piston therein, a housing positioned at 90 to the axis of the piston chamber, said housing having a control valve chamber and a chamber for a piston t0 actuate a control valve, a control valve slidably mounted in said valve chamber and a, piston slidably mounted in said .piston chamber, a connecting rod between the piston and the valve, whereby the valve and piston move as a unit, the chamber for the control valve actuating piston having a pair of fluid inlet ports and a pair of outlet ports, one inletl port and one outlet port of each pair being connected to opposite ends of the chamber, means to connect said fluid pressure inlet ports to the chamber of the freely movable piston at points intermediate the ends thereof, the control valve chamber having a fluid pressure inlet port, a pair of outlet ports and an exhaust port, a conduit connecting the fluid pressure inlet port to the chamber of the freely movable piston at vertically spaced points approximately midway of the length of the chamber, a pair of fluid passages connecting the outlet ports of the control valve chamber with opposite ends of the chamber of the freely movable piston, said passages serving as inlet and exhaust lines for fluid from the control valve chamber to the chamber of the freely movable piston and from said chamber to the exhaust port of the control valve chamber, means formed on the freely movable piston adapted to alternately coact with the fluid pressure inlet ports of its chamber and the passages from said chamber to the valve piston chamber, whereby to introduce liquid under pressure at alternate ends of the chamber of the freely movable piston and reciprocate the piston therein.

vtrol valve slidably mounted in said valve chamber and a piston slidably mounted in said piston chamber,v a connecting rod between the piston and the valve whereby the valve and piston move as a unit, the chamber for the control valve actuating piston having a pair of fluid inlet ports and a pair of outlet ports, one inlet port and one outlet port of each pair being connected to said chamber, a pair of fluid passages connecting the outlet ports of the control valve chamber with opposite ends of the chamber of the freely movable piston, said passages serving 'as inlet and exhaust lines for fluid from the control valve chamber to the chamber of the freely movable piston and from said chamber to the exhaust port of the control valve chamber, means formed on the' freely movable piston comprising a circumferential groove in the vicinity of each end of the piston adapted to alternately coact with the fluid pressure inlet ports of its chamber and the passages from said chamber to the valve pis ton cham-ber, whereby to introduce liquid under pressure at alternate ends of the chamber of the freely movable piston and reciprocate the piston therein. i

GLENN A. CHERRY. WILLIAM D. HANKEY.

REFERENCES CITEDy The follo`wing references are of record in the ille of this patent:

UNITED STATES PATENTS y Date