US3764233A - Submersible motor-pump assembly - Google Patents
Submersible motor-pump assembly Download PDFInfo
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- US3764233A US3764233A US00198679A US3764233DA US3764233A US 3764233 A US3764233 A US 3764233A US 00198679 A US00198679 A US 00198679A US 3764233D A US3764233D A US 3764233DA US 3764233 A US3764233 A US 3764233A
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- pump
- casing
- electric motor
- motor
- bladder
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F04—POSITIVE - DISPLACEMENT MACHINES FOR LIQUIDS; PUMPS FOR LIQUIDS OR ELASTIC FLUIDS
- F04B—POSITIVE-DISPLACEMENT MACHINES FOR LIQUIDS; PUMPS
- F04B17/00—Pumps characterised by combination with, or adaptation to, specific driving engines or motors
- F04B17/03—Pumps characterised by combination with, or adaptation to, specific driving engines or motors driven by electric motors
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F04—POSITIVE - DISPLACEMENT MACHINES FOR LIQUIDS; PUMPS FOR LIQUIDS OR ELASTIC FLUIDS
- F04B—POSITIVE-DISPLACEMENT MACHINES FOR LIQUIDS; PUMPS
- F04B47/00—Pumps or pumping installations specially adapted for raising fluids from great depths, e.g. well pumps
- F04B47/06—Pumps or pumping installations specially adapted for raising fluids from great depths, e.g. well pumps having motor-pump units situated at great depth
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F04—POSITIVE - DISPLACEMENT MACHINES FOR LIQUIDS; PUMPS FOR LIQUIDS OR ELASTIC FLUIDS
- F04D—NON-POSITIVE-DISPLACEMENT PUMPS
- F04D13/00—Pumping installations or systems
- F04D13/02—Units comprising pumps and their driving means
- F04D13/06—Units comprising pumps and their driving means the pump being electrically driven
- F04D13/08—Units comprising pumps and their driving means the pump being electrically driven for submerged use
- F04D13/10—Units comprising pumps and their driving means the pump being electrically driven for submerged use adapted for use in mining bore holes
Definitions
- ABSTRACT A submersible motor-pump assembly including: a reservoir casing which is adapted to contain a hydraulic fluid; a hydraulic pump mounted within the casing, the pump having an inlet which is located within the casing and an outlet which is extended through the casing; an electric motor for purposes of driving the aforementioned hydraulic pump; and the casing having means for equalizing the pressure within the casing with respect to ambient pressure.
- the present invention provides a very compact and streamlined power unit which will operate at deep ocean depths to convert d-c battery power to mechanical energy in the form of high pressure hydraulic fluid.
- This has been accomplished by providing a submersible motor-pump assembly which includes: a reservoir casing which is adapted to contain a hydraulic fluid; a pump mounted within the casing, the pump having an inlet which is located within the casing and an outlet which is extended through the casing; an electric motor for driving the pump; and the casing having means for equalizing the pressure within the casing with respect to ambient pressure.
- the casing may be cylindrical and of thin wall light weight construction.
- An object of the present invention is to provide a compact and reliable power unit which will convert d-c electric energy into mechanical energy in the form of high pressure liquid media.
- Another object is to provide a low cost, low weight, compact, deep submersible power unit which is easy to disassemble and maintain, not effected by depth of pressure, and low in noise level.
- FIG. 1 is a longitudinal cross sectional view of the submersible motor-pump assembly.
- FIG. 1 a submersible motor-pump assembly 10 which includes a reservoir casing 12 which is adapted to contain a hydraulic fluid 14, such as MIL-H-5606 hydraulic oil.
- a pump 16 with its own housing is mounted within the casing and has an intake 18 which is located within the casing and an outlet 20 which is extended through the casing by any suitable means such as pipe 22.
- An electric motor 24, preferably a d-c electric motor is mounted within the casing 12 for driving the pump 16.
- the motor 24 is drivingly connected to the pump 16 by a flexible coupling 26 and has its own housing.
- the casing 12 has means for equalizing the pressure within the casing with respect to the ambient ocean pressure.
- This equalizing means may include the casing 12 having a port 31 which opens to the ambient ocean environment, and the bladder being mounted in the casing 12 so that ambient pressure is applied to the exterior of the bladder.
- the bladder 30 is coextensive with the pump 16 and its appurtenances, to be described hereinafter, since the pump intakes hydraulic oil within this area.
- the pump may be provided with a compensator 32 which is also located within the bladder area.
- the pump 16 may be supported within the casing 12 by a plate 34 which is transversely mounted within the casing 12.
- the plate 34 in combination with a plate 36 and an annular ring 38 adjacent the plate 36 may comprise a means for sealing the ends of the bladder 30 about the pump 16 and compensator 32.
- the plate 34 is in turn mounted to a combination mount 40 to which the electric motor 24 may also be mounted.
- a plate 42 may act as an axial alignment guide for the motor field as well as a mounting bracket for electric sockets 43.
- a space may be provided within the combination mount 40 for the mounting of the flexible coupling 26.
- the plate 34 and combination mount 40 are provided with ports 44 and 46 respectively for comm unicating hydraulic fluid between the pump and flexible coupling spaces. Hydraulic fluid may pass between the flexible coupling and electric motor spaces through the ball bearing 47.
- a removable end plate 48 is transversely mounted within the casing 12 and is spaced from the plate 42.
- the electric motor 24 has brushes 49 which are held within brush holders 50 that are mounted on the removable end plate 48 so as to be located within the space provided between this plate and the plate 42.
- Pins 52 combined with sockets 43 may be utilized for connecting the brushes 49 to the electric motor 24 so that the brushes can be easily removed with the plate 48 for inspection and then easily reconnected to the electric motor after maintenance.
- the motor armature is splined where it mates with the flexible coupling so that it may be removed for commutator maintenance after removal of plate 48.
- the casing 12 may include caps 54 and 56 which are mounted at each end thereof. Male connectors 58 (one shown) may be provided for carrying d-c electric power to the motor 24.
- the cap 54 may have a passageway 60 for receiving a control arm 62 from the compensator 32.
- the control arm 62 may terminate in a control knob 64 outside the housing 28 for selectively adjusting the output pressure of the pump 16 at a desired level above ambient pressure.
- the outlet tube 22 also extends through this cap 54.
- Hydraulic fluid passes through the ball bearing 47 and flows through the annular space between the motor armature and field.
- the plate 42 is shaped like a large washer so that fluid can pass into the brush area.
- a hole 65 allows oil to flow from the brush space into the annular space between the motor and the casing 12.
- hydraulic fluid may be returned to the unit by a pipe 66 through the plate 48.
- hydraulic fluid is circulated through the entire unit carrying away foreign particles which may erode from the brushes and aiding in heat transfer from the motor.
- the hydraulic fluid must be returned by a pipe (not shown) through the plate 36 and a space 67 may be provided for a shaft seal to prevent the passage of hydraulic oil into the motor spaces.
- the motor spaces may be filled with a fluid which is compatible with the brushes such as hydraulic fluid MIL-H-5606.
- This fluid may be compensated to ambient pressure by means of an external compensator (not shown) which is connected to the motor spaces by means of a passageway (not shown) through plate 48.
- the motor spaces may be filled with fluid through this passageway.
- a screw 68 and sealing washer 70 may be provided for bleeding off air trapped withinthe case during the filling process and also for bleeding off gasses generated during operation due to arcing of the brushes.
- filling of the unit with hydraulic fluid is accomplished through the hydraulic fluid return inlet pipe 66.
- the screw 68 is used. to bleed trapped air from the unit.
- a torpedo propulsion motor is utilized since these motors are generally designed for minimum size and weight for a given horsepower and also for maximum efficiency.
- Two examples of such motors are the propulsion motors for the MK-32 torpedo (5 HP) and the MK34 torpedo (11.5 HP).
- the casing 12 may be provided with an annular recess 74 adjacent the exterior of the bladder 30 so as to provide a space for containing seawater therebetween.
- the end plates 36 and 48 may be retained within the housing 28 by snap rings 76 and 78 respectively.
- the spaces where the hydraulic pump oil is located may be sealed from the ambient ocean environment by the various rings shown in FIG. 1.
- the present invention provides a very compact and reliable power unit which will convert d-c battery power to mechanical energy in the form of pressurized hydraulic oil.
- the pressurized hydraulic oil may be utilized for driving hydraulic thrusters on a deep submersible or for other undersea purposes.
- a submersible motor pump comprising:
- a reservoir casing which is adapted to contain a hydraulic fluid
- a pump of the type having a housing with a fluid intake and a fluid outlet;
- conduit means connected to the outlet of the pump and extending through said casing for discharging the hydraulic fluid exterior the casing
- said casing having means for equalizing the pressure within the casing with respect to ambient pressure, the equalizing means including: said casing having a port opening to ambient; and a bladder for containing the liquid media, said bladder being mounted in the casing so that ambient pressure is applied to the exterior of the bladder;
- said casing having an annular interior recess adjacent the exterior of the bladder for providing a space for containing sea water therebetween;
- said casing having a cap mounted at each end thereof;
- conduit means extending the pump outlet through one of the caps
- said casing being generally cylindrical
- said bladder being generally tubular
- an electric motor of the type having a housing
- said electric motor being mounted in one end portion of the cylindrical casing and the pump being mounted in the other end of the portion;
- the electric motor end portion of the casing having a hydraulic fluid inlet for receiving fluid to the assembly;
- the assembly spaces for the motor, driving means, and pump being in liquid communication with one another so that received fluid will first cool the motor and then supply the pump;
- a combination mount disposed within the casing for supporting the pump plate and the electric motor;
- the connecting means between the electric motor and the pump being located within the combination mount;
- said electric motor having brushes which are mounted on the end plate and located within the space between the end plate and said one of the electric motor plates;
- a submersible motor-pump assembly comprising:
- a reservoir casing which is adapted to contain a hydraulic fluid
- said reservoir casing having a pump chamber and a motor chamber; a pump of the type having a housing with a fluid intake and a fluid outlet; means mounting the pump in the pump chamber with the fluid intake of the pump positioned for intaking said hydraulic fluid from within the pump chamber; conduit means connected to the outlet of the pump and extending through said casing for discharging the hydraulic fluid exterior the casing; a bladder mounted in the pump chamber around the pump; and said casing having a port which communicates ambient pressure with the exterior of the bladder.
- a motor-pump assembly as claimed in claim 3 including;
- a motor-pump assembly as claimed in claim 3 including:
- said casing being generally cylindrical; said bladder being generally tubular;
- a motor-pump assembly as claimed in claim 5 including:
- said pump chamber having an annular interior recess adjacent the exterior of the bladder for providing a space for containing sea water therebetween.
- a combination mount disposed within the casing between the pump and motor chambers for supporting the pump plate and the electric motor
- the connecting means betwen the electric motor and pump being a flexible coupling which is located within the combination mount.
- a motor-pump assembly as claimed in claim 7 including:
- the electric motor having brushes which are mounted on the end plate and located within the space between the end plate and said one of the electric motor plates;
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Abstract
A submersible motor-pump assembly including: a reservoir casing which is adapted to contain a hydraulic fluid; a hydraulic pump mounted within the casing, the pump having an inlet which is located within the casing and an outlet which is extended through the casing; an electric motor for purposes of driving the aforementioned hydraulic pump; and the casing having means for equalizing the pressure within the casing with respect to ambient pressure.
Description
United States Patent 1191 Strickland SUBMERSIBLE MOTOR-PUMP ASSEMBLY [75] Inventor: Alvah T. Strickland, Kailua, Hawaii [73] Assignee: The United States of America as represented by the Secretary of the Navy, Washington, DC
[22] Filed: Nov. 15, 1971 [21] Appl. No.: 198,679
[52] US. Cl. 417/414, 417/371 [51] Int. Cl. F04b 35/04 [58] Field of Search 417/360, 371, 410, 417/414, 422, 902
[56] References Cited UNITED STATES PATENTS 2,551,623 5/1951 More 417 902 x 3,237,852 3/1966 Shaw.... 417/902 X 3,041,977 7/1962 Boyd 417/414 3,434,656 3/1969 Bellmer.... 417/371 X 2,759,665 8/1956 Wilber 417/311 X Oct. 9, 1973 1,905,599 4/1933 Nowitsky 417/371 2,897,763 8/1959 Wright 1,891,771 12/1932 Mendenhall et al 417/414 2,060,649 11/1936 Warner 417/414 X 2,455,022 1l/1948 Schmidt....
2,725,824 12/1955 Arutunoff 417/414 Primary Examiner-C. J. Husar Assistant Examiner-Leonard Smith Attorney-Richard S. Sciascia et al.
[57] ABSTRACT A submersible motor-pump assembly including: a reservoir casing which is adapted to contain a hydraulic fluid; a hydraulic pump mounted within the casing, the pump having an inlet which is located within the casing and an outlet which is extended through the casing; an electric motor for purposes of driving the aforementioned hydraulic pump; and the casing having means for equalizing the pressure within the casing with respect to ambient pressure.
.8 Claims, 1 Drawing Figure STATEMENT OF GOVERNMENT INTEREST The invention described herein may be manufactured and used by or for the Government of the United States of America for governmental purposes without the payment of any royalties thereon or therefor.
BACKGROUND OF THE INVENTION The old method of providing power to submersible systems involved only the conversion of d-c electric energy to mechanical energy with no hydraulic intermediary step. With such an arrangement propellers on the submersible were driven directly by electric motors. A disadvantage of this prior art approach is the high cost of d-c submersible electric motors and electronic motor controllers. Also, electronic motor controllers have not demonstrated a high reliability when exposed to ocean pressures.
In reviewing prior art systems which convert d-c electric energy into mechanical energy in the form of high pressure hydraulic oil, one is faced with bulky designs which would not be satisfactory for many deep submersible vehicles. In U. S. Pat. No. 3,434,443 there is disclosed a buoyancy transport vehicle which is operated by a diver and must be compact in order to carry out its intended purposes. This vehicle required a power unit which would utilize battery power to provide hydraulic fluid under pressure for driving various thrusters on the vehicle.
SUMMARY OF THE INVENTION The present invention provides a very compact and streamlined power unit which will operate at deep ocean depths to convert d-c battery power to mechanical energy in the form of high pressure hydraulic fluid. This has been accomplished by providing a submersible motor-pump assembly which includes: a reservoir casing which is adapted to contain a hydraulic fluid; a pump mounted within the casing, the pump having an inlet which is located within the casing and an outlet which is extended through the casing; an electric motor for driving the pump; and the casing having means for equalizing the pressure within the casing with respect to ambient pressure. With such an. arrangement the casing may be cylindrical and of thin wall light weight construction.
STATEMENT OF THE OBJECTS OF INVENTION An object of the present invention is to provide a compact and reliable power unit which will convert d-c electric energy into mechanical energy in the form of high pressure liquid media.
Another object is to provide a low cost, low weight, compact, deep submersible power unit which is easy to disassemble and maintain, not effected by depth of pressure, and low in noise level.
Other objects and many of the attendant advantages of this invention will be readily appreciated as it becomes better understood by reference to the description and accompanying drawings which follow.
BRIEF DESCRIPTION OF THE DRAWING FIG. 1 is a longitudinal cross sectional view of the submersible motor-pump assembly.
DESCRIPTION OF THE PREFERRED EMBODIMENT Referring now to the drawing there is shown in FIG. 1 a submersible motor-pump assembly 10 which includes a reservoir casing 12 which is adapted to contain a hydraulic fluid 14, such as MIL-H-5606 hydraulic oil. A pump 16 with its own housing is mounted within the casing and has an intake 18 which is located within the casing and an outlet 20 which is extended through the casing by any suitable means such as pipe 22.
An electric motor 24, preferably a d-c electric motor is mounted within the casing 12 for driving the pump 16. The motor 24 is drivingly connected to the pump 16 by a flexible coupling 26 and has its own housing.
The casing 12 has means for equalizing the pressure within the casing with respect to the ambient ocean pressure. This equalizing means may include the casing 12 having a port 31 which opens to the ambient ocean environment, and the bladder being mounted in the casing 12 so that ambient pressure is applied to the exterior of the bladder. In the preferred embodiment, the bladder 30 is coextensive with the pump 16 and its appurtenances, to be described hereinafter, since the pump intakes hydraulic oil within this area. In order to establish pump pressure at a selected level above ambient the pump may be provided with a compensator 32 which is also located within the bladder area.
The pump 16 may be supported within the casing 12 by a plate 34 which is transversely mounted within the casing 12. The plate 34 in combination with a plate 36 and an annular ring 38 adjacent the plate 36 may comprise a means for sealing the ends of the bladder 30 about the pump 16 and compensator 32. The plate 34 is in turn mounted to a combination mount 40 to which the electric motor 24 may also be mounted. A plate 42 may act as an axial alignment guide for the motor field as well as a mounting bracket for electric sockets 43. A space may be provided within the combination mount 40 for the mounting of the flexible coupling 26. Further, the plate 34 and combination mount 40 are provided with ports 44 and 46 respectively for comm unicating hydraulic fluid between the pump and flexible coupling spaces. Hydraulic fluid may pass between the flexible coupling and electric motor spaces through the ball bearing 47.
A removable end plate 48 is transversely mounted within the casing 12 and is spaced from the plate 42. The electric motor 24 has brushes 49 which are held within brush holders 50 that are mounted on the removable end plate 48 so as to be located within the space provided between this plate and the plate 42. Pins 52 combined with sockets 43 may be utilized for connecting the brushes 49 to the electric motor 24 so that the brushes can be easily removed with the plate 48 for inspection and then easily reconnected to the electric motor after maintenance. The motor armature is splined where it mates with the flexible coupling so that it may be removed for commutator maintenance after removal of plate 48.
The casing 12 may include caps 54 and 56 which are mounted at each end thereof. Male connectors 58 (one shown) may be provided for carrying d-c electric power to the motor 24. The cap 54 may have a passageway 60 for receiving a control arm 62 from the compensator 32. The control arm 62 may terminate in a control knob 64 outside the housing 28 for selectively adjusting the output pressure of the pump 16 at a desired level above ambient pressure. The outlet tube 22 also extends through this cap 54.
Hydraulic fluid passes through the ball bearing 47 and flows through the annular space between the motor armature and field. The plate 42 is shaped like a large washer so that fluid can pass into the brush area. A hole 65 allows oil to flow from the brush space into the annular space between the motor and the casing 12.
In the preferred embodiment hydraulic fluid may be returned to the unit by a pipe 66 through the plate 48. In this way hydraulic fluid is circulated through the entire unit carrying away foreign particles which may erode from the brushes and aiding in heat transfer from the motor. However, it may be desirable in some cases to use a hydraulic fluid in which d-c electric motor brushes cannot operate satisfactorily. In this case the hydraulic fluid must be returned by a pipe (not shown) through the plate 36 and a space 67 may be provided for a shaft seal to prevent the passage of hydraulic oil into the motor spaces. The motor spaces may be filled with a fluid which is compatible with the brushes such as hydraulic fluid MIL-H-5606. This fluid may be compensated to ambient pressure by means of an external compensator (not shown) which is connected to the motor spaces by means of a passageway (not shown) through plate 48. The motor spaces may be filled with fluid through this passageway. A screw 68 and sealing washer 70 may be provided for bleeding off air trapped withinthe case during the filling process and also for bleeding off gasses generated during operation due to arcing of the brushes.
In the preferred embodiment filling of the unit with hydraulic fluid is accomplished through the hydraulic fluid return inlet pipe 66. The screw 68 is used. to bleed trapped air from the unit.
In the preferred embodiment a torpedo propulsion motor is utilized since these motors are generally designed for minimum size and weight for a given horsepower and also for maximum efficiency. Two examples of such motors are the propulsion motors for the MK-32 torpedo (5 HP) and the MK34 torpedo (11.5 HP).
In order to dampen the sound of the operation of the pump 16 the casing 12 may be provided with an annular recess 74 adjacent the exterior of the bladder 30 so as to provide a space for containing seawater therebetween. By such an arrangement noise vibrations of the pump 16 must travel through the hydraulic oil 14, bladder 30, seawater within the space 74, and the. housing 28 before transmission to the outside ocean environment. These many interfaces considerably reduce the noise generated by the pump 16.
The end plates 36 and 48 may be retained within the housing 28 by snap rings 76 and 78 respectively. The spaces where the hydraulic pump oil is located may be sealed from the ambient ocean environment by the various rings shown in FIG. 1.
It is now readily apparent that the present invention provides a very compact and reliable power unit which will convert d-c battery power to mechanical energy in the form of pressurized hydraulic oil. The pressurized hydraulic oil may be utilized for driving hydraulic thrusters on a deep submersible or for other undersea purposes.
Obviously many modifications and variations of the present invention are possible in the light of the above teachings. It is therefore to be understood that within the scope of the appended claims the invention may be practiced otherwise than as specifically described.
I claim:
1. A submersible motor pump comprising:
a reservoir casing which is adapted to contain a hydraulic fluid;
a pump of the type having a housing with a fluid intake and a fluid outlet;
means mounting the pump in the casing with the fluid intake of the pump positioned for intaking said hydraulic fluid from within the casing;
conduit means connected to the outlet of the pump and extending through said casing for discharging the hydraulic fluid exterior the casing;
said casing having means for equalizing the pressure within the casing with respect to ambient pressure, the equalizing means including: said casing having a port opening to ambient; and a bladder for containing the liquid media, said bladder being mounted in the casing so that ambient pressure is applied to the exterior of the bladder;
said casing having an annular interior recess adjacent the exterior of the bladder for providing a space for containing sea water therebetween;
said casing having a cap mounted at each end thereof;
said conduit means extending the pump outlet through one of the caps;
said casing being generally cylindrical;
said bladder being generally tubular;
means for sealing the ends of the bladder within the casing;
an electric motor of the type having a housing;
said electric motor being mounted in one end portion of the cylindrical casing and the pump being mounted in the other end of the portion;
means drivingly connecting the pump to the electric motor;
the electric motor end portion of the casing having a hydraulic fluid inlet for receiving fluid to the assembly;
the assembly spaces for the motor, driving means, and pump being in liquid communication with one another so that received fluid will first cool the motor and then supply the pump;
a plate transversely mounted within the casing for supporting the pump;
a combination mount disposed within the casing for supporting the pump plate and the electric motor;
the connecting means between the electric motor and the pump being located within the combination mount;
a removable end plate transversely mounted within the casing and spaced from one of the electric motor plates;
said electric motor having brushes which are mounted on the end plate and located within the space between the end plate and said one of the electric motor plates; and
pin and socket means connecting the brushes to the electric motor.
2. A submersible motor-pump assembly comprising:
a reservoir casing which is adapted to contain a hydraulic fluid;
said reservoir casing having a pump chamber and a motor chamber; a pump of the type having a housing with a fluid intake and a fluid outlet; means mounting the pump in the pump chamber with the fluid intake of the pump positioned for intaking said hydraulic fluid from within the pump chamber; conduit means connected to the outlet of the pump and extending through said casing for discharging the hydraulic fluid exterior the casing; a bladder mounted in the pump chamber around the pump; and said casing having a port which communicates ambient pressure with the exterior of the bladder. 3. A submersible motor-pump assembly as claimed in claim 2 including:
said reservoir casing being elongated; an electric motor of the type having a housing; said electric motor being mounted in the motor chamber; the motor chamber having a hydraulic fluid inlet for receiving hydraulic fluid to the reservoir casing so as to supply the pump and cool the electric motor. 4. A motor-pump assembly as claimed in claim 3 including;
said casing having a cap mounted at each end thereof; and said conduit means extending the pump outlet through one of the caps. 5. A motor-pump assembly as claimed in claim 3 including:
said casing being generally cylindrical; said bladder being generally tubular; and
means for sealing the ends of the bladder within the pump chamber.
6. A motor-pump assembly as claimed in claim 5 including:
said pump chamber having an annular interior recess adjacent the exterior of the bladder for providing a space for containing sea water therebetween.
7. A motor-pump assembly as claimed in claim 6 including:
a plate transversely mounted within the pump casing for supporting the pump;
a combination mount disposed within the casing between the pump and motor chambers for supporting the pump plate and the electric motor; and
the connecting means betwen the electric motor and pump being a flexible coupling which is located within the combination mount.
8. A motor-pump assembly as claimed in claim 7 including:
a removable end plate transversely mounted within the motor chamber and spaced from one of the electric motor plates;
the electric motor having brushes which are mounted on the end plate and located within the space between the end plate and said one of the electric motor plates; and
pin and socket means connecting the brushes to the electric motor,
whereby the brushes can be removed with the end plate for inspection and then easily reconnected to the electric motor.
Claims (8)
1. A submersible motor pump comprising: a reservoir casing which is adapted to contain a hydraulic fluid; a pump of the type having a housing with a fluid intake and a fluid outlet; means mounting the pump in the casing with the fluid intake of the pump positioned for intaking said hydraulic fluid from within the casing; conduit means connected to the outlet of the pump and extending through said casing for discharging the hydraulic fluid exterior the casing; said casing having means for equalizing the pressure within the casing with respect to ambient pressure, the equalizing means including: said casing having a port opening to ambient; and a bladder for containing the liquid media, said bladder being mounted in the casing so that ambient pressurE is applied to the exterior of the bladder; said casing having an annular interior recess adjacent the exterior of the bladder for providing a space for containing sea water therebetween; said casing having a cap mounted at each end thereof; said conduit means extending the pump outlet through one of the caps; said casing being generally cylindrical; said bladder being generally tubular; means for sealing the ends of the bladder within the casing; an electric motor of the type having a housing; said electric motor being mounted in one end portion of the cylindrical casing and the pump being mounted in the other end of the portion; means drivingly connecting the pump to the electric motor; the electric motor end portion of the casing having a hydraulic fluid inlet for receiving fluid to the assembly; the assembly spaces for the motor, driving means, and pump being in liquid communication with one another so that received fluid will first cool the motor and then supply the pump; a plate transversely mounted within the casing for supporting the pump; a combination mount disposed within the casing for supporting the pump plate and the electric motor; the connecting means between the electric motor and the pump being located within the combination mount; a removable end plate transversely mounted within the casing and spaced from one of the electric motor plates; said electric motor having brushes which are mounted on the end plate and located within the space between the end plate and said one of the electric motor plates; and pin and socket means connecting the brushes to the electric motor.
2. A submersible motor-pump assembly comprising: a reservoir casing which is adapted to contain a hydraulic fluid; said reservoir casing having a pump chamber and a motor chamber; a pump of the type having a housing with a fluid intake and a fluid outlet; means mounting the pump in the pump chamber with the fluid intake of the pump positioned for intaking said hydraulic fluid from within the pump chamber; conduit means connected to the outlet of the pump and extending through said casing for discharging the hydraulic fluid exterior the casing; a bladder mounted in the pump chamber around the pump; and said casing having a port which communicates ambient pressure with the exterior of the bladder.
3. A submersible motor-pump assembly as claimed in claim 2 including: said reservoir casing being elongated; an electric motor of the type having a housing; said electric motor being mounted in the motor chamber; the motor chamber having a hydraulic fluid inlet for receiving hydraulic fluid to the reservoir casing so as to supply the pump and cool the electric motor.
4. A motor-pump assembly as claimed in claim 3 including; said casing having a cap mounted at each end thereof; and said conduit means extending the pump outlet through one of the caps.
5. A motor-pump assembly as claimed in claim 3 including: said casing being generally cylindrical; said bladder being generally tubular; and means for sealing the ends of the bladder within the pump chamber.
6. A motor-pump assembly as claimed in claim 5 including: said pump chamber having an annular interior recess adjacent the exterior of the bladder for providing a space for containing sea water therebetween.
7. A motor-pump assembly as claimed in claim 6 including: a plate transversely mounted within the pump casing for supporting the pump; a combination mount disposed within the casing between the pump and motor chambers for supporting the pump plate and the electric motor; and the connecting means between the electric motor and pump being a flexible coupling which is located within the combination mount.
8. A motor-pump assembly as claimed in claim 7 including: a removable end plate transversely mounted within the motor chamber and spaced from one Of the electric motor plates; the electric motor having brushes which are mounted on the end plate and located within the space between the end plate and said one of the electric motor plates; and pin and socket means connecting the brushes to the electric motor, whereby the brushes can be removed with the end plate for inspection and then easily reconnected to the electric motor.
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US19867971A | 1971-11-15 | 1971-11-15 |
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US00198679A Expired - Lifetime US3764233A (en) | 1971-11-15 | 1971-11-15 | Submersible motor-pump assembly |
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Cited By (59)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
EP0024581A1 (en) * | 1979-08-24 | 1981-03-11 | Bolenz & Schäfer Maschinenfabrik GmbH & Co. KG | Device for charging pressure accumulators in hydraulic systems with a highly compressed gas |
FR2485678A1 (en) * | 1980-06-26 | 1981-12-31 | Toyo Denki Kogyosho Co Ltd | METHOD AND MECHANISM FOR CONTROLLING PRESSURE TO PARTS SECURING A TREE OF A DEVICE AND A FLUID TRANSPORT PUMP USING THE SAME |
US4324534A (en) * | 1978-05-26 | 1982-04-13 | Andrew Master Hones Limited | Power supply apparatus |
US4751939A (en) * | 1985-01-29 | 1988-06-21 | Societe Nationale Elf Aquitaine (Production) | Immersed hydraulic unit for controlling an underwater oil working station |
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