Downhole oil well pump

An automatic gas operated downhole fluid pump having an elongated cylindrical chamber for receiving fluid and having a concentrically mounted cylindrical float which is connected to a valve having an actuator biased and retained in either an opened or closed position with an elongated control rod connected with the valve actuator and extending through a passageway through the cylindrical float with adjustable means to adjustably connect the control rod with the cylindrical float to apply force to the actuator only when it is desired to actuate the valve.

BACKGROUND OF THE INVENTION 
This invention relates generally to a downhole oil well pump and more 
particularly to a pump which is air-operated and actuated by the oil level 
in the well. 
It has been known before to provide a downhole oil well pump, which is 
air-operated and responsive to oil level in the well. An example of this 
is shown in U.S. Pat. No. 4,092,087, issued May 30, 1978. This device 
discloses a pumping mechanism using a valve 47 having a reciprocating 
valve member and locking means to retain the valve member in a closed 
position. The problem with this device is that the valve is expensive to 
manufacture and maintain which greatly increases the cost of the pump 
mechanism. It is very important that the valve mechanism be reliable since 
the pump is positioned in the well well below the surface. This requires 
that the valve operate continuously and reliably over a period of time 
without removal of the pump which increases the cost of pumping the well. 
The oil well pump of this invention is used in wells having what is 
considered marginal production. These wells normally would be shut in due 
to the cost and difficulty of pumping the small amounts in production 
which they are capable of producing. In order to make production from such 
wells justifiable, it is necessary that an inexpensive and reliable pump 
mechanism be provided which will be dependable in operation in which can 
operate for periods of time without much maintenance and inspection. 
SUMMARY OF THE INVENTION 
The invention relates to a downhole air operated oil well pump apparatus 
which may be positioned in a borehole in stages for sequentially pumping 
oil to the surface. The apparatus includes a lost-motion valve acuator and 
a toggle valve having a toggle member moveable between open and closed 
positions to selectively supply air to the pump when the oil reaches a 
predetermined level and to cut off the air supply when the oil drops to a 
second predetermined level due to pumping to the surface or the next 
stage. The apparatus may be connected in series for deep wells.

BRIEF DESCRIPTION OF THE PREFERRED EMBODIMENT 
Referring to FIG. 1 of the drawings, there is shown a pump system 10 having 
a plurality of pumping stages 11, 12, and 13 positioned in a tubing string 
14 extending into a producing formation 15. 
An oil flow line 16 is provided and extends from the surface S to the 
pumping stage 13. A second oil flow line 17 extends from the pumping stage 
13 to the second pumping stage 12. A third oil flow line 18 extends from 
the pumping stage 12 to the pumping stage 11. Additional oil flow lines 
and stages could be provided depending on the depth of the formation. An 
air supply line 19 extends from the surface S to the first stage 13. A tee 
20 in the air supply line 19 is connected to a line 21 which supplies air 
to the pumping stage 13. As will be apparent the air supply line 19 is 
connected to a suitable source of compressed air to power the pumps for 
pumping the oil between the various pumping stages and to the surface. 
Another air supply line 22 is connected to the air supply line 19 and 
supplies air from the pumping stage 13 to the pumping stage 12. A tee 23 
is positioned in the air supply line 22 and is connected to an air supply 
line 24 which supplies air to the pumping stage 12. The air supply line 22 
is connected to an air supply line 25 which extends from the pumping stage 
12 to the pumping stage 11. These pumping stages could generally be 
positioned at three hundred (300) to four hundred (400) feet intervals as 
is required to pump oil from the well depending on the depth of the 
formation. 
The pumping stage 13 includes an air exhaust line 25 which allows oil to 
fill the stage and lets air out of the stage. The pumping stage 12 
likewise includes an air exhaust line 26 which functions similarly. The 
pumping stage 11 includes an air exhaust line 27 which has its upper end 
28 extending above the upper surface 15(a) of the producing formation 15. 
Each of the pumping stages is identical so a detailed description is 
provided of only one stage. Referring to FIG. 2 of the drawing, there is 
shown a pumping stage 29. Each stage includes a generally cylindrical 
housing 30 having an upper cap member 31 and a lower cap member 32. The 
cap members are designed for interconnecting the stages and for connecting 
air supply or exhaust lines and the oil producing lines. 
The upper cap member 31 is sealingly secured to the housing as is the lower 
cap member 32 which defines a chamber 33. The chamber 33 receives oil from 
the formation in the case of the lower pumping stage or from the adjacent 
lower pumping stage in the case of the pumping stages positioned above the 
lower pumping stage. Positioned in the chamber 33 is an oil exhaust line 
34 which is off-set from the center as best shown in FIGS. 3 and 4. A 
transverse channel 35 in the upper cap member connects the oil exhaust 
line 35 to a second oil exhaust line 36 which extends upwardly from each 
pumping stage. The transverse channel is formed by boring a hole into the 
cap member to connect the oil producing lines 34 and 36. A plug 37 is 
provided to close off the channel from the exterior of the cap mwmber. As 
will be apparent, the cap member is secured in the cylindrical housing 30 
with a plurality of set screws 38, 39, 40, 41, and 42 as shown in FIGS. 3 
and 4. An O-ring is provided to provide a seal between the cap member and 
the housing. 
As shown in FIG. 2(a), an air supply line 44 from the surface is connected 
to the cap member 31. A channel 45 extends through the cap member to 
communicate with the air supply line 44 and an air supply line 46 which 
extends through the chamber 33 to the lower cap member where it may be 
connected to the next stage. 
Air is supplied to the stage 29 through air supply line 47 as shown in FIG. 
2(a). The air supply line 47 is connected to the air supply 44 by means of 
a tee as best shown in FIG. 1. A channel 48 extends through the cap member 
31 to supply air from the air supply line 47 to another air supply line 49 
which is connected to the toggle valve V having toggle control T. 
The toggle valve V is connected to an exhaust conduit 50 as best shown in 
FIG. 2(c) by means of a connector 51. The exhaust channel 50 is connected 
to an exhaust line 52 shown in FIG. 2(a). 
In operation the toggle valve V, with a mechanism as disclosed in U.S. Pat. 
No. 2,860,660, supplies pressurized air through the opening 53 as shown in 
FIG. 2(c) or allows air within the chamber 33 to exhaust through the 
opening 53 when the chamber is being filled with oil. In FIG. 2 the toggle 
valve V is shown in its air supply position whereby air is being supplied 
to the chamber 33. In FIG. 2(a) the toggle valve V is shown in its air 
exhaust position whereby air is allowed to exhaust from the chamber 33 as 
it is filled with oil. Secured to the toggle control T is a connector 
member 54 which is pivotally connected to a link 55. Link 55 is in turn 
pivotally connected to another connector 56 which is connected to 
adjustable control rod 57. A control rod 57 extends downward to where it 
is connected to a float F as shown in FIGS. 2 and 2b. The Float F 
comprises a sealed container having a passageway 58 therethrough for 
slidably receiving the oil producing line 34. The float F includes another 
passage 59 for slidably receiving the air supply line 46. Taps 60, 61, 62, 
and 63 allow the control rod 57 to be adjustably connected with the float. 
They also provide a loss motion connector so that the weight of the float 
is not on the toggle control T except when it is desired to activate the 
valve. This protects the valve from strain or damage whent the float is in 
its lowermost position at rest on the stop 67 and during the filling of 
the chamber before it is desired to open the valve and supply pressurized 
air to the chamber. 
The lower cap member 32 is sealingly secured with the housing 30 in the 
same manner as the upper cap 31. An O-ring 64 is provided to provide the 
seal. The cap member 32 includes a passageway 65 extending thereto for 
connecting with air supply line 46. In the case of the lower stage, the 
passage way 65 would be merely capped off. The lower cap 32 includes a 
second passageway 66. As shown in FIG. 2(b), a check valve 66 may be 
provided for the lower stage. All stages above the lower state would be 
connected to an oil exhaust line such as oil exhaust line 6 which would 
likewise be connected with the lower cap member of the next stage through 
another check valve. 
In operation, the oil enters the chamber 33 though check valve 66. The 
toggle valve V is in the position shown in FIG. 2 which allows air to 
exhaust through line 52. When the float F reaches an upper predetermined 
condition, it will engage the tap 61 and any further upward movement of 
the float F will apply pressure the toggle valve V and toggle control T 
through the control rod 57. When the oil reaches a predetermined level, 
sufficient force will be applied to the toggle control T to overcome the 
predetermined force necessary to move it to its air supply position as 
shown in FIG. 2(a). The buoyancy of the float is predetermined to supply 
the sufficient force. This will result in air being supplied to the 
chamber 33 and closing of the exhaust line 52. Oil in the chamber will be 
forced through the oil exhaust line 34 upwardly and outwardly oil exhaust 
line 36. As the oil is forced through the oil exhaust line, the float F 
will again move downward until it engages the tap 62. The weight of the 
float F is such that it will overcome the predetermined force necessary to 
move the toggle control T from the position shown in FIG. 2(a) to that 
shown in FIG. 2 whereby the air supply will be cut off and the air exhaust 
line will again be connected through the chamber 33. 
The toggle V provides quick and certain connection of the chamber 33 of the 
air supply line or the air exhaust line. The tap 61 and 62 can be 
positioned so that the float activates the toggle control at a 
predetermined position of the float within the chamber. The float has a 
predetermined volume for bouyancy and weight which is selected to properly 
activate the toggle control T. 
A stop member 67 is positioned through passageway 68 to engage the lower 
surface of the float. The stop member 67 can be adjustably positioned to 
determine the lower most limit of the float F. A cap member 69 is provided 
to seal the passageway 68. Passageway 65 is sealed in the case of the 
lower unit with a plug such as plug 69. In the case of stages above the 
lower stage the air supply line 44 would be connected with the passageway 
65. 
Although the invention has been described in conjunction with the foregoing 
specific embodiment, many alternatives, variations and modifications will 
be apparent to those of ordinary skill in the art. Those alternatives, 
variations and modifications are intended to fall within the spirit and 
scope of the appended claims.