US3294024A

US3294024A - Pumping system

Info

Publication number: US3294024A
Authority: US
Inventors: Charles O Meyers; Maurice S Hoss
Original assignee: Combustion Engineering Inc
Current assignee: Combustion Engineering Inc
Priority date: 1964-06-10
Filing date: 1964-06-10
Publication date: 1966-12-27
Anticipated expiration: 1983-12-27

Description

Dec. 27, 1966 c. o. MEYERS ETAL 3,294,024

PUMPING SYSTEM 5 Sheets-Sheet 1 Filed June 10, 1964 INVENTORS. CHARLES O. MEYERS MAURICE 5. H055 BY KL/ ATTORNEY Dec. 27, 1966 c. o. MEYERS ETAL. 3,294,024

PUMPING SYSTEM 5 Sheets-Sheet 2 Filed June 10, 1964 INVENTORS. CHARLES O. MEYERS BY MAURICE 5. :2

NW4? M;

A T TORNE Y 1965 c. o. MEYERS ETAL 3,294,024

PUMPING SYSTEM 5 Sheets-Sheet 5 Filed June 10, 1964 INVENTORS. CHARLES 0. MEYERS MAURICE 5. H055 BY ATTORNEY United States Patent 3,294,024 PUMPING SYSTEM Charles 0. Meyers and Maurice S. Hoss, Tulsa, Okla., assiguors to Combustion Engineering, Inc., New York County, N.Y., a corporation of Delaware Filed June 10, 1964, Ser. No. 373,929 2 Claims. (Cl. 103--21) available for producing water from deep subterranean sands. However, the control of pumping has not been developed to properly protect the pumping equipment, conserve the available water or produce most efiiciently from a minimum supply.

The centrifugal type pumps in common use will be damaged if allowed to run dry. Therefore, it is important that a water well be produced as to guard against lowering the well level to the point of withdrawal by the pump. At the same time the pump is controlled so it will not run dry, the pump operation must be carried out so as to account for a water table relatively high with respect to the depth of the well and relatively low with respect to well depth. I

A principal object of the invention is to supply water to a varying demand at a predetermined maximum pressure.

Another object is to supply water at a predetermined maximum rate, when the water table is relatively high, while maintaining a predetermined level in the reservoir of the well bore.

Another object is to produce Water from a well, when the water table is relatively low, at the maximum capacity of the well reservoir without running the pump dry.

The present invention contemplates completing a well bore deep enough to provide a reservoir of water in the bore. A power source is then mounted at the top of the bore and connected to pump elements within the bore to withdraw water from the reservoir. The pumping is then controlled under two general conditions. First, when the water table is relatively high with respect to the depth of the Well bore, the pumping is carried out to withdraw water so as to maintain a predetermined maximum output pressure. Second, when the water table is relatively low with respect to the depth of the well bore, the pumping is carried out to withdraw water so as to maintain a reservoir level as low as practical without lowering the level to the point of withdrawal.

To control the pumping of the Water from the well reservoir, a restrictive element in the output of the pump is positioned by a control system responsive to level detector devices suspended in the well bore. The control system operates the control element in three different ways. First, the control element is opened at a predetermined rate when the reservoir level is above the level detectors. Second, the control element is closed at a predetermined rate when the reservoir level is below the level detectors. Third, the control element is held in the position attained when the level has been moved to between the level detectors. As the third position of the control element is a combination of the times within which the control element is being opened and closed, the position of the element when the level is between the detectors is established to balance the rate of supply of water into the bore from the water table in supplying the demand for water.

Other objects, advantages and features of this invention will become apparent to one skilled in the art upon consideration of the written specification, appended claims and attached drawings, wherein;

FIG. 1 is a diagrammatic representation of a water well extending to a depth well below the water table and equipped with pumping equipment in which the present invention is embodied;

FIG. 2 is similar to FIG. 1 but with the water table indicated as relatively low with respect to the bottom of the well; and

FIG. 3 is a schematic illustration of the circuit between the level detectors and the control valve motor windings.

General arrangement of apparatus Referring to FIGS. 1 and 2, we have shown a well shaft 1 sunk from the ground surface 2 to a distance below a subterranean water sand 3. The sand 3 stratum may vary in depth. One variation is indicated, the sand rising to some distance indicated at 4.

The shaft I normally has a casing 5 which is perforated at 6 to let water flow readily from sand stratum 3 into the shaft 1. It is expected that the water will flow through perforations 6 from a level above the top of sand 3 at 7 or from level 8 which is below the top of sand 3.

During the rainy season of the year, the general water table is expected to be relatively high with respect to the bottom of the well shaft 1. The exact height, or depth of the water table from surface 2, will depend upon the water flowing into the area generally. We have arbitrarily placed line 7 as an indication of this height.

When water is plentiful, i.e., the Water table level is at 7, the problem of pumping is simply one of supplying the demand at a predetermined maximum pressure. The problem becomes more complex when the scarcity of water lowers the water table. Line 8 has been established to represent this height. Then the withdrawal of water from the well reservoir becomes an art in keeping as low a well level, within shaft 1, as possible without lowering the level to the intake end of the pump. The pump must not run dry but as high a gradient as practical must be maintained between 8 and the well level. Both methods of operation are carried out by the proper control of pump 9 which is mounted on the end of column pipe 11.

Column pipe 11 is suspended from some type of base at the surface 2. We have illustrated a simple concrete slab 12 which is formed over and beyond casing 5. A motor housing 13 is mounted on a base member which is mounted on the top of slab 12. The base member supports pipe 11 in shaft 1 from the upper end 14 of pipe 11. Shaft 15 mechanically connects the pump motor within housing 13 to the several stages of blades within pump 9.

The water withdrawn from the reservoir in casing 5 is forced up column pipe 11, through base member 16 and out conduit 17 for use. Mounted in output conduit 17 is a valve 18 which is positioned to develop a back pressure on the pump output in control of the Withdrawal from the reservoir in shaft 1. Valve 18 is positioned by an electric motor 19, the motor 19 being controlled by a circuit Within the unit 20.

Probe 21 and probe 22 are suspended in the well shaft 1, and are located specifically between column pipe 11 and easing 5. No specific arrangement has been illustrated for suspending

probes

21, 22 in the Well shaft or for adjusting their vertical positions independently within the shaft. Various mechanical arrangements for supporting and adjusting the probes can be made. The basic disclosure of the invention is furthered by developing that these probes are of the conductance type and by such characteristic transmit distinguishing signals to unit 20 when the level of water is above the probes, between the probes and below the probes.

Electrical power sources for the motor within housing 13 and the system Within unit 20 are indicated. Such electrical power is now generally available even in remote locations throughout the United States where wells of this type are located.

Operation The pump is desirably a constant speed, centrifugal, type. Therefore, the rate of water withdrawn is established by the setting of valve 18 by motor 19 to maintain 5 back-pressure on the pump.

The general system of control is arranged to maintain the setting of valve 18 for as long as thelevel of the reservoir is between the

probes

21, 22. If the, level goes above the upper probe 21 the valve 18 starts opening. If the level then drops below probe 21 thenew opening of valve 18 is maintained. If the level continues to fall and drops below probe 22, the valve 18 starts toclose. If the level then rises to probe 22 the valve 18 opening is maintained. Eventually, with these actions on valve 18, a position will be found for valve 18 which will keep the well level between the

probes

21, 22. The flow into vthe well reservoir will then be balanced against the flow out of conduit 17.

Downstream demand for the water of circuit 17 may change. Then the valve 18 will have to be readjusted to the change in pressure drop .across the valve. If the demand is too'great for the available in-flow of water into the well reservoir, the well level will sink below the probe 22 and valve 18 will close, opening only as the well level rises above probe 21. If the well supply is greater than the demand, the valve 18 will open as the well level goes above probe 21, closing only when the well level sinks below probe 22.

FIG. 1 is arranged to show the condition of operation when the water table is high, i.e., the level 7 is well above the bottom of shaft 1.

Probes

21 and 22 are shown with the well reservoir level between them. Valve 18 is set to permit withdrawal of water through conduit 17 at a rate to match the flow of water through perforakeeping the reservoir level above probe 22, the probe 21 will open the valve 18 when the reservoir level rises above probe 21.

FIG. 3 shown the basic circuit for controlling motor 19 by

probes

21, 22. Unit 20 of FIGS. 1 and 2 is illustrated as oriented to the windings of motor 19 and probes 21, 22. It was previously indicated that probes 21, 22 were of the conductance type. In FIG. 3, their cooperation with the circuit of unit 20, to controlmotor 19, is

shown in sufficient detail for the purpose of disclosing the present invention.

The basic purpose of unit 20 is to connect a power supply 30 (220 v.) to winding 31 or winding 32. Winding 31 will turn motor 19 to close Valve 18 when energized. Winding 32 will open valve 18 when energized.

The circuit within unit 20 responds to

probes

21, 22 to selectively energize the motor windings.

The circuit of unit 20 is shown in, its condition when the water level in the well shaft 1 is below probe 22.

Switch arm 33 is making contact with 34,- connecting winding 31 with source 30; so energized, motor 19 is rotating to close valve 18 and thereby permit the water flowing into the well shaft to rise.

The position of arm 33 is controlled by coil 35. When coil 35 is energized, arm 33 is pulled downinto'engagement with contact 36. Coil 35 is in circuit with the plate and grid of tube 37. The tube 37 is a gas-filled tube which conducts when the grid voltage is reduced to a predetermined value.

A transformer 38 is supplied from a source 39 v.). Secondary winding 40 is in series with coil 35 and when tube 37 is allowed to conduct, coil 35 is energized to pull down arm 33. Secondary winding 41 has a portion of its output voltage applied to the grid of tube 37 to keep the tube 37 from conducting.

All that is necessary to reduce the grid voltage of tube 37 enough to fire tube 37 is to connect the grid to ground; this is done through probe 22. When the water of the well raises toprobe 22 the grid is grounded, tube 37 conducts and coil 35 is energized. Valve 18 is held in the position it had when the water level reached probe 22 and disconnected winding 31 from source 30. i

Switch arm 33 is pulled down to contact arm 36, thereby connecting source 30 to switch arm 42. The water level is between the two probes. Both windings of the motor 19 are cle-energized untilthe water level reaches upper probe 21 or falls below probe 22.

Tube .43 controls coil 44 in the same manner as tube 37 controlled coil 35. Source 45 supplies a transformer which supplies power for coil 44 and a grid voltage for tube 43. Contact of probe 21 with the water connects the grid to ground and permits the .tube to conduct. Coil 44 is energized and arm 42 is pulled down into contact with 46. Motor winding 32 is thereby connected to source 30 and valve 18 is moved toward its open position until probe 21 is uncovered.

The operation of the valve 18 by

probes

21, 22 is now completely described. The water between the probes fixes the valve position wherever it was when the level came between the probes. If the level sinks below the lower probe the valve closes; if the level rises above the upper probe the valve opens. When the level is between the probes,the valve does not move. The output from the well is thereby controlled by a search for the valve position which will balance the inflow to the well reservoir with the water drawn from conduit 17.

With the unit 20 responding to probes as disclosed,

the positioning of the probeswithin the well bore will carry out the objects of the invention.

- From the foregoing it will be seen that this invention is one well adapted to attain all of the ends and objects hereinabove set forth, together with other advantages which are obvious and which are inherent to the method and apparatus.

It will be understood that certain features and subcombinations are of utility and may be employed without reference to other features and subcombinations. This is contemplated by and is within the scope of the claims.

As many possible embodiments may be made of the invention without departing from the scope thereof, it is to be understood that all matter herein set forth or shown in the accompanying drawings is to be interpreted as illustrative and not in a limiting sense.

The present invention having been described, what is claimed is: I

1. A system with which to produce a water wall, in.- cluding,

a wellbore extended from the ground surface to form a reservoir of water in the bottom of the bore,

a column pipe extending from the ground surface and within the bore to a .point near the bottom of the bore, Y r

pump elements mounted within the pump shaft so as to draw water from the reservoir and up the column pipe to the ground surface,

means for powering the pump elements connected to the pump elements,

a valve mounted in the pump discharge,

first and second level detection elements spaced vertically in the well bore,

and an electrical circuit connected to the level detec tion elemQ ltS. and the valveto control the setting of the valve in accordance with the position of the water level in the well bore with respect to the level detection elements,

whereby the valve will be moved toward full open as long as the water level is above both elements, the valve will be held at the setting reached as the water level is brought to between the elements and the valve will be moved toward full closed as long as the water level is below both elements.

2. A system for transfer of liquid from a source to point of deposit, including,

a source of liquid,

a receptacle for liquid from the source,

a conduit connecting the source and receptacle,

a pump connected to the conduit for moving the liquid from the source through the conduit to the receptacle,

a valve mounted in the conduit,

first and second level detection elements spaced vertically with respect to a level of the liquid,

and an electrical circuit connected to the level detection elements and the valve to control the valve setting,

References tCited by the Examiner UNITED STATES PATENTS Kingsbury 137-392 Kirgan 103-97 Fillo 137-392 Buck 103-25 Arndt 103-25 McDaniel 103-25 Kusner 1034O Rudy et al. 103-25 20 MARK NEWMAN, Primary Examiner. W. J. KRAUSS, Assistant Examiner.

Claims

1. A SYSTEM WITH WHICH TO PRODUCE A WATER WALL, INCLUDING, A WELL BORE EXTENDED FORM THE GROUND SURFACE TO FORM A RESERVOIR OF WATER IN THE BOTTOM OF THE BORE, A COLUMN PIPE EXTENDING FROM THE GROUND SURFACE AND WITHIN THE BORE TO A POINT NEAR THE BOTTOM OF THE BORE, PUMP ELEMENTS MOUNTED WITHIN THE PUMP SHAFT SO AS TO DRAW WATER FROM THE RESERVOIR AND UP THE COLUMN PIPE TO THE GROUND SURFACE, MEANS FOR POWERING THE PUMP ELEMENTS CONNECTED TO THE PUMP ELEMENTS, A VALVE MOUNTED IN THE PUMP DISCHARGE, FIRST AND SECOND LEVEL DETECTION ELEMENTS SPACED VERTICALLY IN THE WELL BORE, AND AN ELECTRICAL CIRCUIT CONNECTED TO THE LEVEL DETECTION ELEMENTS AND THE VALVE TO CONTROL THE SETTING OF THE VALVE IN ACCORDANCE WITH THE POSITION OF THE WATER LEVEL IN THE WELL BORE WITH RESPECT TO THE LEVEL DETECTION ELEMENTS, WHEREBY THE VALVE WILL BE MOVED TOWARD FULL OPEN AS LONG AS THE WATER LEVEL IS ABOVE BOTH ELEMENTS, THE VALVE WILL BE HELD AT THE SETTING REACHED AS THE WATER LEVEL IS BROUGHT TO BETWEEN THE ELEMENTS AND THE VALVE WILL BE MOVED TOWARD FULL CLOSED AS LONG AS THE WATER LEVEL IS BELOW BOTH ELEMENTS.