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1. Field of the Invention
The present invention relates to oil well pumps. More particularly, the present invention relates to a downhole oil well pump apparatus that uses a circulating working fluid to drive a specially configured pump that is operated by the working fluid and wherein the pump transmits oil from the well to the surface by commingling the pumped oil with the working fluid, oil and the working fluid being separated at the wellhead or earth's surface. Even more particularly, the present invention relates to an oil well pump that is operated in a downhole cased, production pipe environment that utilizes a pump having a single pump shaft that has gerotor devices at each end of the pump shaft, one of the gerotor devices being driven by the working fluid, the other gerotor device pumping the oil to be retrieved.
2. General Background of the Invention
In the pumping of oil from wells, various types of pumps are utilized, the most common of which is a surface mounted pump that reciprocates between lower and upper positions. Examples include the common oil well pumpjack, and the Ajusta® pump. Such pumps reciprocate sucker rods that are in the well and extend to the level of producing formation. One of the problems with pumps is the maintenance and repair that must be performed from time to time.
The present invention provides an improved pumping system from pumping oil from a well that provides a downhole pump apparatus that is operated with a working fluid that operates a specially configured pumping arrangement that includes a common shaft. One end portion of the shaft is a gerotor that is driven by the working fluid. The other end portion of the shaft has a gerotor that pumps oil from the well. In this arrangement, both the oil being pumped and the working fluid commingle as they are transmitted to the surface. A separator is used at the earth's surface to separate the working fluid (for example, water) and the oil.
For a further understanding of the nature, objects, and advantages of the present invention, reference should be had to the following detailed description, read in conjunction with the following drawings, wherein like reference numerals denote like elements and wherein:
Oil well pump apparatus 10 as shown in the sectional elevation view of
The apparatus 10 of the present invention provides an oil well pump 10 that has a tool body 15 that is elongated to fit inside of the bore 18 of production tubing 12 as shown in
Prime mover 121 can be a commercially available pump that receives working fluid via flowline 122 from reservoir 123. Reservoir 123 is supplied with the working fluid such as water via flowline 124 that exits oil/water separator 125.
As the working fluid is pumped by prime mover 121 in the direction of arrows 20 through production tubing 12, the working fluid enters tee-shaped passage 34 as indicated by arrows 21. The working fluid then travels in sleeve bore 36 of sleeve 35 as indicated by arrows 22 until it reaches connector 60 and its flow passages 67. Arrows 23 indicate the flow of the working fluid from the passages 67 to retainer 111 and its passageways 112, 113. At this point, the working fluid enters pump mechanism 26 (see
The pump mechanism 26 is driven by the working fluid. The pump mechanism 26 also pumps oil from the well in the direction of oil flow arrows 27 as shown in
Oil that flows from the producing formation in to the tool body (see arrows 27) flows upwardly via bore 86 of seating nipple 14. The lower end portion 17 of tool body 15 has a tapered section 84 that is shaped to fit seating nipple 14 as seen in
Check valve 88 and its spring 89 prevent the working fluid from flowing into the formation that contains oil. The oil producing formation is below packer 13 and check valve 88. The producing oil enters the production tubing bore 18 via perforations (not shown) as is known in the art for oil wells. The check valve 88 is overcome by the pump 26 pressure as oil is pumped upwardly in the direction of arrows 27. The pump 26 includes two central impellers or rotors 94, 95. The upper central rotor 94 and outer rotor 98 are driven by the working fluid. The lower central rotor 95 and outer rotor 99 are connected to the upper rotor 94 with shaft 91 so that the lower central rotor 95 rotates when the upper rotor 95 is driven by the working fluid. Thus, driving the upper rotor 94 with the working fluid simultaneously drives the lower rotor 95 so that it pumps oil from the well production bore 18. The oil that is pumped mixes with the working fluid at perforations 114 in the production tubing as indicated schematically by the arrows 28, 29 in
In
As an alternate means to lower the tool body 15 into the well (if not using pumping of
An upper filter 30 is provided for filtering the working fluid before it enters the pump mechanism 26. A lower filter 31 is provided for filtering oil before it enters the pump mechanism 26.
The tool body 15 includes a sleeve 35 that can be attached with a threaded connection 38 to the lower end portion of neck section 32 as shown in
Valve housing 48 has external threads that enable a threaded connection 49 to be formed with sleeve 52 at its bore 53 that is provided with internally threaded portions. The bore 53 of sleeve 52 carries filter 30 which is preferably in the form of a plurality of filter disks 54 separated by spacers 108 (see FIGS. 1B, 8-9). As shown in 7A, the filtered disks 54 of filter 30 are held in position upon shaft 57 with retainer plate 55 and bolt 56. Shaft 57 has an internally threaded portion 58 for receiving bolt 56 as shown in
The pump mechanism 26 (see
The housing 63 has a working fluid discharge port 65 and an oil discharge port 66 (see
Each of the central rotors 94, 95 fits an outer rotor that has a star shaped chamber. In
Each rotor 94, 95 has multiple lobes (e.g., four as shown). The upper rotor 94 has lobes or gear teeth 100, 101, 102, 103. The lower rotor 95 has floor or gear teeth lobes 104, 105, 106, 107. This configuration of a star shaped inner or central rotor rotating in a star shaped chamber of an outer rotor having one more lobe than the central or inner rotor is a per se known pumping device known as a “gerotor”. Gerotor pumps are disclosed, for example, in U.S. Pat. Nos. 3,273,501; 4,193,746, 4,540,347; 4,986,739; and 6,113,360 each hereby incorporated herein by reference.
Working fluid that flows downwardly in the direction of arrow 23 enters the enlarged chamber 113 part of passageway 112 of retainer 111 so that the working fluid can enter any part of the star shaped chamber 109 of upper disk 98. An influent plate 115 is supported above upper disk 98 and provides a shaped opening 116. When the working fluid is pumped from enlarged section 113 into the star shaped chamber 109 that is occupied by upper rotor 94, both rotors 94 and 98 rotate as shown in
The two gerotor devices 150, 151 provided at the keyed end portions 92, 93 of shaft 91 each utilize an inner and outer rotors. At shaft upper end 92, upper inner rotor 94 is mounted in star shaped chamber 109 of peripheral rotor 98. As the inner, central rotor 94 rotates, the outer rotor 98 also rotates, both being driven by the working fluid that is pumped under pressure to this upper gerotor 150.
The rotor or impeller 94 rotates shaft 92 and lower inner rotor or impeller 95. As rotor 95 rotates with shaft 92, outer peripheral rotor 99 also rotates, pulling oil upwardly in the direction of arrows 27. Each inner, central rotor 94, 95 has one less tooth or lobe than its associated outer rotor 98, 99 respectively as shown in
As working fluid flows through passageways 112, 113 into star shaped chamber 109 and shaped opening 116, rotors 94, 98 rotate as do rotors 95, 99. Oil to be produced is drawn through suction ports 133, 134 of retainer 132 to shaped opening 136 of effluent plate 117 and then into star shaped chamber 110 of outer rotor 99. The rotating rotors 95, 99 transmit the oil to be pumped via passageway 135 to oil discharge port 66.
At discharge port 66, oil to be produced mixes with the working fluid and exits perforations 114 in production tub 12 as indicated by arrows 28 in
In the pumping mode of
When the lower gerotor 151 turns, it pumps produced oil into the casing annulus 19 so that it commingles (arrows 28) with the working fluid and returns to the surface. At the surface or wellhead 120, the oil/water separator 125 separates produced oil into a selected storage tank and recirculates the power fluid into the reservoir to complete the cycle.
In the retrieval mode of
In
The following is a list of suitable parts and materials for the various elements of the preferred embodiment of the present invention.
10 oil well pump
11 casing
12 production tubing
13 packer
14 seating nipple
15 tool body
16 upper end portion
17 lower end portion
18 bore
19 annulus
20 arrow
21 arrow
22 arrow
23 arrow
24 arrow
25 check valve
26 pump mechanism
27 oil flow arrow
28 oil mix flow arrow
29 return flow arrow
30 filter, upper
31 filter, lower
32 neck section
33 annular shoulder
34 channel
35 sleeve
36 sleeve bore
37 swab cup
38 threaded connection
39 annular socket
40 swab cup
41 annular socket
42 spacer sleeve
43 bore
44 swab cup
45 spacer sleeve
46 bore
47 annular socket
48 valve housing
49 threaded connection
50 spring
51 passageway
52 sleeve
53 bore
54 filter disk
55 retainer plate
56 bolt
57 shaft
58 internal threads
59 threaded connection
60 connector
61 external threads
62 external threads
63 pump mechanism housing
64 internal threads
65 working fluid discharge port
66 produced oil discharge port
67 flow passage
68 connector
69 external threads
70 external threads
71 flow passage
72 shaft
73 threaded connection
74 retainer plate
75 bolt
76 filler disk
78 threaded connection
79 threaded connection
80 sleeve
81 bore
82 internal threads
83 threaded connection
84 tapered section
85 external threads
86 bore
87 o-ring
88 check valve
89 spring
90 internal threads
91 shaft
92 keyed portion
93 keyed portion
94 upper rotor
95 lower rotor
96 shaped opening
97 shaped opening
98 outer rotor
99 outer rotor
100 lobe
101 lobe
102 lobe
103 lobe
104 lobe
105 lobe
106 lobe
107 lobe
108 spacer
109 star shaped chamber
110 star shaped chamber
111 retainer
112 passageway
113 enlarged section
114 perforations
115 influent plate
116 shaped opening
117 effluent plate
118 arrow
119 arrow
120 wellhead area
121 prime mover
122 flowline
123 reservoir
124 flowline
125 separator
126 flowline
127 arrow
128 flowline
129 arrow
130 three way valve
131 handle
132 retainer
133 suction port
134 suction port
135 passageway
136 shaped opening
137 passageway
140 reference dot
141 reference dot
150 upper gerotor device
151 lower gerotor device
The foregoing embodiments are presented by way of example only; the scope of the present invention is to be limited only by the following claims.