A rotating shaft is supported by journal bearings that can support without contacting the rotating shaft itself. Then, one end of both shaft end portions of the rotating shaft has a main impeller installed and the other end is provided with a sub impeller. By utilizing a force being generated by rot
A rotating shaft is supported by journal bearings that can support without contacting the rotating shaft itself. Then, one end of both shaft end portions of the rotating shaft has a main impeller installed and the other end is provided with a sub impeller. By utilizing a force being generated by rotation of the main impeller, liquid being pumped (fluid being pumped) is sucked in through a suction port and discharged through a discharge port. On the other hand, by utilizing a force being generated by rotation of the sub impeller, fluid is transported to the journal bearings, thereby having the journal bearings support the rotating shaft.
대표청구항▼
What is claimed is: 1. A sealless pump comprising: a manifold unit being provided with a suction port and a discharge port, and a motor unit housing a rotating shaft, wherein the rotating shaft is supported by non-contact type bearings which provide support without contacting the rotating shaft, a
What is claimed is: 1. A sealless pump comprising: a manifold unit being provided with a suction port and a discharge port, and a motor unit housing a rotating shaft, wherein the rotating shaft is supported by non-contact type bearings which provide support without contacting the rotating shaft, a first impeller being installed to one end of the rotating shaft and a second impeller being installed to other end of the rotating shaft, fluid being pumped is sucked in through the suction port and discharged through the discharge port by utilizing a force being generated by rotation of the first impeller, the non-contact type bearings support the rotating shaft, by utilizing a force being generated by rotation of the second impeller so as to transmit fluid for lubrication to the non-contact type bearings, the first impeller has first blade portions installed in a radial direction with respect to an axis of the first impeller, and outside and inside shrouds installed on the first blade portions, the outside shroud has a first confronting surface which communicates with the discharge port and a second confronting surface which communicates with the suction port, the first confronting surface and the second confronting surface facing the same direction, the fluid at the discharge port applies pressure to the first confronting surface and the fluid at the suction port applies pressure to the second confronting surface, and the area of the first confronting surface is smaller than the area of the second confronting surface. 2. The sealless pump as described in claim 1, wherein the non-contact type bearings are installed so as to have first gaps with the rotating shaft therebetween, and the second impeller forms a fluid film in the first gaps between the non-contact type bearings and the rotating shaft by transmitting the fluid for lubrication to the non-contact type bearings with the force being generated by rotation. 3. The sealless pump as described in claim 1, wherein the non-contact type bearings are cylindrical journal bearings which surround the rotating shaft, wherein depressed areas serving as first gaps are formed on inner circumference surfaces of the journal bearings, the second impeller forms fluid films inside the depressed areas by transmitting the fluid for lubrication to inside of the depressed areas, and the fluid films being formed support the rotating shaft with static pressure of the fluid for lubrication. 4. The sealless pump as described in claim 1, wherein, by providing a first flow pathway which connects the suction port and the discharge port, a circulation flow pathway for the fluid being pumped where the fluid being pumped circulates between the suction port and the discharge port is formed, and by connecting a second flow pathway, where the fluid for lubrication being transmitted by the second impeller flows to the non-contact type bearings, and a third flow pathway, where the fluid reaching the non-contact type bearings flows to the second impeller, a circulation flow pathway for bearings where the fluid for lubrication circulates between the second impeller and the non-contact bearings is formed. 5. The sealless pump as described in claim 4, wherein the circulation flow pathway for bearings has a heat exchanger provided. 6. The sealless pump as described in claim 1, wherein the other end of the rotating shaft is provided with a thrust bearing supporting load acting on the rotating shaft in a thrust direction through the second impeller, and the second impeller, by transmitting fluid being generated by rotation to the thrust bearing, forms a fluid film between the thrust bearing and the second impeller. 7. The sealless pump as described in claim 6, wherein the second impeller has second blade portions installed in a radial direction with respect to an axis of the second impeller, and has second side-plates installed so as to hold rotating surfaces of the second blade portions, the second side-plates are held by the thrust bearing and provided so as to have second gaps between the side-plates and the thrust bearing, and the second impeller, by transmitting the fluid for lubrication to the clearances with the force being generated by rotation, forms the fluid films between the second side-plates and the thrust bearing. 8. The sealless pump as described in claim 7, wherein depressed areas serving the second gaps between the second side-plates and the thrust bearing are formed on holding surfaces of the thrust bearing, the second impeller, by transmitting the fluid for lubrication to inside of the depressed areas, forms fluid films inside depressed areas, and the fluid films being formed support the second impeller with static pressure of the fluid for lubrication. 9. The sealless pump as described in claim 7, wherein the second side-plates of the second impeller are vertical plane surfaces with respect to the axis of the second impeller. 10. The sealless pump as described in claim 1, further comprising: a cylindrical filling member which has an end portion facing the first confronting surface, and which prevents liquid being pumped from leaking from the discharge port to the suction port are provided so as to surround the first side-plates and to be located close to a space between the first side-plates and an inner wall of a manifold casing of the manifold unit. 11. The sealless pump as described in claim 1, wherein by rotating of the second impeller, fluid flowing to the non-contact type bearings which are installed to the rotating shaft flows from the first impeller to the second impeller. 12. The sealless pump as described in claim 11, wherein, a bypass flow pathway which goes through continuously inside and outside of a motor casing of the motor unit housing the rotating shaft is installed to the motor casing on a side of the second impeller. 13. The sealless pump as described in claim 1, wherein supercritical fluid or liquid circulates as the fluid being pumped.
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