The present invention relates to a pump and a pumping system utilizing the same, and more particularly, to a pumping device with an improved rotor to enhance the pumping efficiency of freshwater or seawater, and a pumping system utilizing the same.
Generally, pumps are largely classified into turbo types and positive displacement types according to pumping theory. Turbo pumps feature a high feed rate but a relatively small size and are configured for a low delivery head and a large volume of fluid. Centrifugal pumps belong to the turbo pumps. Positive displacement pumps are configured for a high delivery head and a low flow rate, and a feed rate is almost constant under any delivery head ranges. The positive displacement pumps include gear pumps, reciprocating pumps, screw pumps, etc.
Centrifugal pumps include an impeller and a casing. The centrifugal pumps are devices in which a centrifugal force is generated when rotating a fluid in a high speed with an impeller, and the fluid is directed to the circumference from the center of the impeller through a pressure change caused by the centrifugal force. Gear pumps are operated in such a way to push a fluid from an inlet side to an outlet side while two gears in a casing are rotated engagingly with each other. The gear pumps are configured for a small volume of fluid and are mainly used to deliver oils such as a lubricant.
With respect to screw pumps, Utility Model Registration No. 0167567 discloses a screw operator in which a screw impeller having an anti-scattering film is inserted into a case member having a coupling hole and a plurality of guiding blades.
As apparent from the above description, a centrifugal pump, which is a turbo pump, has a representative advantage capable of delivering a large volume of fluid but is configured for a low delivery head. A gear pump, which is a positive displacement pump, can optionally raise a delivery head, thereby guaranteeing a high pumping efficiency, but has a disadvantage that cannot significantly increase a feed rate due to its structural characteristics. A screw pump can pump a large volume of water, but has a disadvantage that cannot raise a delivery head.
When pumping freshwater for drinking purpose or seawater to a nursery area using such a screw pump or centrifugal pump, water pumping efficiency is relatively low, thereby incurring considerable maintenance costs.
The present invention provides a pumping device capable of relatively increasing water pumping efficiency using the rotary strength and centrifugal force of a screw, and a pumping system utilizing the same.
The present invention also provides a pumping system that is simple in maintenance and management and is easy in adjustment of a pumping depth.
The present invention also provides a pumping system that can constantly maintain a water intake location below the surface of water and can convert a centrifugal force to the lifting power of water.
According to an aspect of the present invention, there is provided a pumping device including a rotor, the rotor including: a screw pumping unit including a rotary body which is rotatably supported by a rotary shaft installed in a frame and a screw installed between an inner surface of the rotary body and an outer surface of the rotary shaft to form a pumping passage; and a centrifugal pumping unit, disposed on the screw pumping unit, radially ejecting water pumped by the screw pumping unit under a centrifugal force.
The rotary body and the screw of the screw pumping unit may have a diameter gradually decreasing toward the centrifugal pumping unit from the bottom of the pumping device.
According to another aspect of the present invention, there is provided a pumping device including a rotor, the rotor including: a screw pumping unit including an inner body rotatably supported by a rotary shaft installed in a frame, an outer body separated from the inter body by a predetermined body to surround the inner body, and a plurality of wings installed between the inner body and the outer body to form a spiral pumping passage; and a centrifugal pumping unit, disposed on the screw pumping unit, radially ejecting water pumped by the screw pumping unit under a centrifugal force.
A distance between an outer surface of the inner body and the outer body may be constantly maintained, and the inner body and the outer body may have a diameter gradually increasing from the bottom to the top of the pumping device.
According to another aspect of the present invention, there is provided a pumping system including: a tower, installed at a water intake place, having an internal space section and a water-bearing section disposed on the internal space section; an outlet pipe connecting the water-bearing section and a reservoir installed on land; an intake pipe which communicates with the internal space section, extends to the water intake place from a lower portion of the tower, and has an upward folded end, a hood being installed at the upward folded end; and a pumping device, installed in the tower, pumping water entered into the internal space section via the intake pipe to the water-bearing section and including: a rotary shaft vertically installed in the tower; a rotor including a screw pumping unit and a centrifugal pumping unit disposed on the screw pumping unit, the screw pumping unit including an inner body installed slidably along the rotary shaft and having a shaft bearing and a buoyancy space, an outer body separated from the inner body by a predetermined distance to surround the inner body, and a plurality of wings installed between the inner body and the outer body to form a spiral pumping passage, and the centrifugal pumping unit radially ejecting water pumped by the screw pumping unit under a centrifugal force; and a driver installed in the tower to drive the rotor.
The driver may include a motor including: a driven pulley having a length which is substantially the same as a lifting distance of the rotor along the rotary shaft supported by the shaft bearing; and a driving pulley connected to the driven pulley via a belt.
A distance between an outer surface of the inner body and the outer body of the screw pumping unit may be constantly maintained, and the inner body and the outer body may have a diameter gradually increasing from the bottom to the top of the pumping device.
As described above, the present invention provides a pumping device and a pumping system utilizing the same. The pumping device, which is positioned in a tower installed in a water intake place, includes a screw pumping unit and a centrifugal pumping unit, and thus, water lifting and suction are simultaneously performed by means of a screw, thereby increasing water pumping power.
While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it will be understood by those of ordinary skill in the art that various changes in form and details may be made from the exemplary embodiments of the present invention.
Therefore, the scope of the present invention for which protection is sought should be defined only by the following claims.
A pumping system according to the present invention is installed to be adjacent to a river, a lake, or a sea in order to draw freshwater, seawater, or the like toward land through an intake pipe extended to a water intake place and to pump the drawn water to a reservoir installed on land. An embodiment of the pumping system is illustrated in
Referring to
The tower 13 includes a pumping device 20 pumping water supplied into the vertical space section 11 via the intake pipe 16 to the water-bearing section 12 and then to the reservoir 100 via the outlet pipe 14.
The tower 13 is a concrete structure and has therein the vertical space section 11 and the water-bearing section 12 disposed on the vertical space section 11 to receive water pumped by the pumping device 20. A flow passage is defined along an inner surface of the water-bearing section 12 of the tower 13 so that pumped water is discharged into the outlet pipe 14 by a centrifugal pumping unit of a rotor as will be described later.
Although not shown, an observation platform may be disposed on the tower 13, and additional facilities may be installed on an outer surface of the tower 13.
The pumping device 20 is used to pump water entered into the vertical space section 11 of the tower 13 via the intake pipe 16 to the water-bearing section 12. An embodiment of the pumping device 20 is illustrated in
Referring to
The screw pumping unit 22 of the rotor 21 includes a rotary body 22a surrounding the rotary shaft 24 vertically rotatably installed in the vertical space section 11 and being radially spaced from the rotary shaft 24 by a predetermined distance; and a screw 22c installed between an outer surface of the rotary shaft 24 and an inner surface of the rotary body 22a to form a spiral pumping passage 22b. With respect to the screw pumping unit 22, the diameters of the screw 22c and the rotary body 22a may be gradually decreased from the bottom to the top thereof to relatively increase an initial intake quantity of water, as illustrated in
The centrifugal pumping unit 23 of the rotor 21 includes a lower plate member 23a radially extended from an upper end of the rotary body 22a; an upper plate member 23b, installed at the rotary shaft 24, being separated from the lower plate member 23a by a predetermined distance; and blades 23c disposed between the upper plate member 23b and the lower plate member 23a to extend radially with respect to the rotary shaft 24. The blades 23c are spirally twisted at a predetermined angle. The rotary body 22a is connected to the rotary shaft 24 via the screw 22c, and thus, the screw pumping unit 22 and the centrifugal pumping unit 23 are rotated together with the rotary shaft 24.
The rotary shaft 24 of the rotor 21 is rotatably installed in a state wherein both ends of the rotary shaft 24 are supported in the tower 13. In order to prevent vibration during rotation, at least a side of an outer surface of the screw pumping unit 22 may be supported by a journal bearing or a roller. Of course, the rotary shaft 24 may also be rotatably supported by a separate frame.
The driver 25 may be a motor 25a installed in an upper portion of the tower 13 to drive the rotary shaft 24. A driving shaft of the motor 25a may be connected to the rotary shaft 24 by power transmission elements, e.g., driving and driven pulleys and belts.
Referring to
The rotor 32 includes a screw pumping unit 33 and a centrifugal pumping unit 34. The screw pumping unit 33 includes an inner body 33a installed coaxially with the rotary shaft 31; an outer body 33b which is separated from the inner body 33a by a pre-determined distance and has a greater diameter than the inner body 33a; and wings 33d installed between the inner body 33a and the outer body 33b to form a pumping passage 33c.
The centrifugal pumping unit 34 has substantially the same structure as those of the previous embodiments, and includes a lower plate member 34a radially extended from an upper end of the outer body 33b; an upper plate member 34b, installed at the rotary shaft 31, being separated from the lower plate member 34a by a predetermined distance; and blades 34c disposed between the upper plate member 34b and the lower plate member 34a to extend radially with respect to the rotary shaft 31. The number of the blades 34c may be the same as the number of the wings 33d, and the blades 34c may radially extend with respect to the wings 33d.
The driver 35 has the same structure as those of the previous embodiments, and thus, a description thereof will be omitted.
Referring to
The rotor 42 has a space in which buoyancy is generated, and includes a screw pumping unit 43 and a centrifugal pumping unit 44. The screw pumping unit 43 includes an inner body 43b that has a buoyancy space 43a and is installed to move slidably along the rotary shaft 41; an outer body 43c separated from the inner body 43b by a predetermined distance to surround the inner body 43b; and wings 43e installed between the inner body 43b and the outer body 43c to form a pumping passage 43d.
In order for the inner body 43b to be installed to move slidably along the rotary shaft 41, a shaft bearing 43f is installed to be bored through the buoyancy space 43a of the inner body 43b, and the rotary shaft 41 is slidably supported by the shaft bearing 43f. A bearing 43g may be installed between the shaft bearing 43f and the rotary shaft 41.
The centrifugal pumping unit 44 has substantially the same structure as those of the previous embodiments, and thus, a description thereof will be omitted.
The driver 46 includes a driven pulley 46a that extends from an upper portion of the rotor 42 along the rotary shaft 41 and has a predetermined diameter; a driving pulley 46c installed at a rotary shaft of a motor 46b installed in the tower 13; and a belt 46d connecting the driven pulley 46a and the driving pulley 46c. The driven pulley 46a of the driver 46 has a length equal to a lifting distance of the rotor 42.
The driver 46 may also include a motor 53 installed at a frame 52 moving up and down along a guide 51 installed at an inner surface of a tower 13; and a rotary shaft 54 connected to a driving shaft of the motor 53, as illustrated in
The screw pumping unit 43 may be structured such that the diameters of the inner body 43b and the outer body 43c are increased gradually from the bottom to the top while constantly maintaining a width of a pumping space, i.e., a distance between the inner body 43b and the outer body 43c, as illustrated in
The actions of pumping systems having the above-described structural characteristics according to the present invention will now be described.
First, referring again to
In a state wherein water is supplied into the vertical space section 11, as illustrated in
The thus-pumped water is supplied to a reservoir 100 via a water-bearing section 12 and an outlet pipe 14.
Referring again to
In particular, as illustrated in
Therefore, it is possible to increase the pumping power of water which is to be pumped by the screw pumping unit 43. The pumped water is re-pumped by a centrifugal pumping unit 44, thereby increasing pumping efficiency.
In addition, a pumping device having a buoyancy space can pump water entered into a vertical space section of a tower at a predetermined depth from a ground surface. In particular, when pumping seawater, the pumping can be achieved regardless of a variation in level of seawater entered into a vertical space section which is caused by the ebb and flow of the tide.
Number | Date | Country | Kind |
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10-2006-0001913 | Jan 2006 | KR | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/KR2007/000084 | 1/5/2007 | WO | 00 | 7/4/2008 |