The present invention relates to a fluid machine that rotates a rotor according to rotation of a rotary shaft to transport fluid.
Recently, there has been a demand for easy-to-assemble fluid machines, and fluid machines in which a rotary shaft is efficiently assembled with a casing have been proposed (see Patent Documents 1 and 2).
The fluid machine disclosed in Patent Document 1 has a casing that is divided into two parts, or an upper casing member and a lower casing member. A rotary shaft is inserted through a ring (block body) with a bearing and a shaft sealing device. A protrusion protruding from the ring is fitted to a recess portion of the lower casing. Then, the upper casing member is assembled to the lower casing member to assemble the fluid machine.
The fluid machine disclosed in Patent Document 2 is a multistage vacuum pump. The vacuum pump has a casing including an upper casing member and a lower casing member, and a plurality of pump operation chambers are defined in the casing. A drive shaft and a driven shaft are each supported to the lower casing member with a bearing and a shaft sealing device. The drive shaft has a drive gear and a plurality of drive rotors, and the driven shaft has a driven gear and a plurality of driven rotors. The upper casing member is assembled to the lower casing member to assemble the fluid machine. Before the upper casing member is assembled to the lower casing member, a clearance between each rotor and an inner surface of a pump operation chamber is adjusted. An engagement position of the drive gear and the driven gear that are timing gears is adjusted to adjust the phase difference between the drive rotor and the driven rotor.
When the fluid machine disclosed in Patent Document 1 is assembled, the ring and the bearing are separated from the lower casing member after the rotary shaft is supported to the lower casing member with the ring. Similarly, when the fluid machine disclosed in Patent Document 2 is assembled, the bearing is separated from the lower casing member after the rotary shaft is supported to the lower casing member with the bearing. Further, in the fluid machine disclosed in Patent Document 2, if the bearing is separated from the lower casing member, the phase difference between the drive rotor and the driven rotor cannot be accurately adjusted. Therefore, in some cases, the upper casing member is assembled to the lower casing member with an inaccurate phase difference between the drive rotor and the driven rotor.
An objective of the present invention is to provide a fluid machine that suppresses a bearing from being separated from a housing during the assembly operation of the fluid machine.
To achieve the foregoing objective, a fluid machine having a rotary shaft, a housing that supports the rotary shaft with a bearing, and a rotor that is provided on the rotary shaft is provided. The housing has the bearing. The rotor is rotated by rotation of the rotary shaft. The fluid machine transports fluid according to the rotation of the rotor. The housing has a two-piece structure having a lower housing member and an upper housing member that is joined to the lower housing member. The lower housing member has a lower bearing support portion that is open upward. The upper housing member has an upper bearing support portion that makes a pair with the lower bearing support portion. The upper bearing support portion is open downward. The lower bearing support portion and the upper bearing support portion support the bearing. An uppermost portion of the lower bearing support portion is positioned above a center of the bearing. An opening width of the lower bearing support portion is smaller than the diameter of the bearing.
According to this configuration, when assembling the fluid machine, a portion of the lower bearing support portion that is above the center of the bearing engages with the bearing in a state where the rotary shaft and the bearing are attached to the lower housing member. This suppresses the bearing from being separated upward from the lower housing member. Therefore, for example, when the bearing is press-fitted to the lower casing member, the bearing is suppressed from being separated from the lower housing member even if an upward force acts on the bearing. In a state where a plurality of rotary shafts are arranged in the lower housing member with bearings, when a timing gear is engaged with each rotary shaft so as to be meshed with each other, the bearing is suppressed from being separated from the lower housing member even if an upward force acts on the bearing.
The lower housing member may have a joint surface that contacts the upper housing member. The entire joint surface is preferably positioned on a same plane. One of the joint surfaces of the lower housing member is a continuous surface that contacts the upper housing member.
According to this configuration, for example, compared to a case in which the lower housing member is processed such that the joint surface has steps, the housing is easily manufactured. Since the whole area of the joint surface is positioned on a single plane, the upper housing member and the lower housing member are flush with each other at a joint portion. This improves the sealing property of the joint portion.
The lower housing member has a lower shaft accommodation portion that accommodates the rotary shaft and a joint surface that contacts the upper housing member. It is preferable that the height of a portion of the joint surface that corresponds to at least the lower shaft accommodation portion is set to be the same as an axis of the rotary shaft.
According to this configuration, for example, when a portion of the joint surface that corresponds to the lower shaft accommodation portion is positioned above the axis of the rotary shaft, the opening width of the lower shaft accommodation portion needs to be greater than the diameter of the rotary shaft such that the rotary shaft is attached to the lower housing member from above smoothly. Therefore, a space exists between the lower shaft accommodation portion and the rotary shaft. However, if the height of the portion of the joint surface that corresponds to the lower shaft accommodation portion is set to be the same as the axis of the rotary shaft, the space between the lower shaft accommodation portion and the rotary shaft becomes smaller. This easily suppresses fluid that is transported by the rotor from passing through the space between a peripheral surface of the rotary shaft and the lower shaft accommodation portion and leaking therefrom.
The lower housing member has a lower shaft accommodation portion that accommodates the rotary shaft. A shaft insertion portion is defined in the lower shaft accommodation portion. The shaft insertion portion preferably has an opening width that is greater than the diameter of a portion of the rotary shaft that is accommodated in the lower shaft accommodation portion.
The rotary shaft can be inserted to the shaft insertion portion from above. Therefore, the rotary shaft can be inserted to the lower shaft accommodation portion from above.
The housing has a seal accommodation portion. The seal accommodation portion accommodates a cylindrical sealing member that seals a space between an inner peripheral surface of the housing and a peripheral surface of the rotary shaft. The seal accommodation portion has a lower seal accommodation portion that is formed in the lower housing member and an upper seal accommodation portion that is formed in the upper housing member. The lower seal accommodation portion opens upward. The upper seal accommodation portion makes a pair with the lower seal accommodation portion. The upper seal accommodation portion opens downward. A shaft insertion portion into which the rotary shaft is inserted is formed in the lower seal accommodation portion. The shaft insertion portion has an opening width that is greater than the diameter of a portion of the rotary shaft that is accommodated in the seal accommodation portion.
The rotary shaft can be inserted to the shaft insertion portion from above. Therefore, the rotary shaft can be inserted to the lower seal accommodation portion from above. The sealing member seals a space between the peripheral surface of the rotary shaft and the inner peripheral surface of the seal accommodation portion. This suppresses the fluid from leaking from the space.
The rotary shaft is one of a drive shaft and a driven shaft that are aligned so as to be parallel to each other in the housing. A drive gear provided on the drive shaft is meshed with a driven gear that is provided on the driven shaft. Rotation of the drive shaft is transmitted from the drive gear to the driven gear such that the driven shaft is rotated synchronously with the drive shaft. Accordingly, a drive rotor that is provided on the drive shaft and a driven rotor that is provided on the driven shaft are engaged to each other so as to be rotatable.
For example, when the drive gear is engaged with the driven gear in a state where the drive rotor is engaged with the driven rotor, the bearing may be separated from the lower housing member. However, the lower bearing support portion suppresses the bearing from being separated. Accordingly, the drive gear is easily engaged with the driven gear.
A first embodiment which applies a fluid machine of the present invention into a Roots pump will be explained with reference to
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Similarly, a lower surface of the upper housing member 20 forms a flat upper joint surface 20a that contacts the lower housing member 10. The entire upper joint surface 20a is positioned on a same plane. The joint portion of the upper joint surface 20a and the lower joint surface 10a forms a joint portion 50 of the housing 2.
The two-piece structure is a structure where the upper housing member 20 is joined to the lower housing member 10 in a state where the lower joint surface 10a of the lower housing member 10 fully contacts the upper joint surface 20a of the upper housing member 20 without having any steps.
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The two straight portions 111a face each other with respect to the width direction of the Roots pump 1. The two straight portions 111a define a shaft insertion portion 111c therebetween. The drive shaft 3 or the driven shaft 4 can be inserted to the shaft insertion portion 111c from above.
The width between the two straight portions 111a, or an accommodation opening width T3 of the lower shaft accommodation portion 11a, is set to be greater than the large diameter D3 of the front drive portion 3b and the front driven portion 4b. In other words, the accommodation opening width T3 is set to be greater than the diameter (D3) of a portion of the drive shaft 3 and the driven shaft 4 that is accommodated in the lower shaft accommodation portion 11a.
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Two rear lower support portions 13 are recessed at a rear side of the rear lower seal accommodation portion 12 in the rear portion of the lower housing member 10. The two rear lower support portions 13 are arranged so as to be aligned along the width direction of the Roots pump 1. Each of the rear lower support portions 13 corresponds to a rear lower bearing support portion that supports the corresponding one of the rear bearings 32, 33. The rear lower support portion 13 is formed in an arc having a larger diameter than the rear lower seal accommodation portion 12 as seen from a front side. Each of the rear lower support portions 13 accommodates a second sealing member 35. Each second sealing member 35 is located between the corresponding first sealing member 34 and the corresponding one of the rear bearings 32, 33.
For example, the first sealing member 34 and the second sealing member 35 are each one of or a combination of two or more of an oil seal, a mechanical seal, and an oil slinger. The steps formed between the front drive portion 3b and the rear drive portion 3a are located between the first sealing member 34 and the second sealing member 35. Similarly, the steps formed between the front driven portion 4b and the rear driven portion 4a are located between the first sealing member 34 and the second sealing member 35. The front drive portion 3b and the front driven portion 4b correspond to (face) the first sealing member 34 and the lower shaft accommodation portion 11a. The rear drive portion 3a and the rear driven portion 4a each correspond to (face) one of the second sealing members 35 and the corresponding one of the rear bearings 32, 33.
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Each rear lower support portions 13 is formed in an arc having an angle greater than 180 degrees. That is, the portion of each rear lower support portion 13 that is above the centers P1 extends along an outer peripheral surface of the corresponding one of the bearings 32, 33. In other words, the portion of each rear lower support portion 13 that is above the centers P1 protrudes toward the corresponding one of the rear bearings 32, 33. The inner peripheral surface of each rear lower support portion 13 extends to the lower joint surface 10a that is positioned above the imaginary plane H.
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The front portion of the upper housing member 20 has two front upper support portions 25 each of which corresponds to one of the front lower support portions 17. An opening width of each front upper support portion 25 is same as an opening width of each front lower support portion 17.
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Each rear lower support portion 13 and the corresponding rear upper support portion 23 form a rear bearing support portion 82. Each rear bearing support portion 82 forms a bearing accommodation zone that is greater than an outer size of the rear bearing 32, 33. Each of the rear bearings 32, 33 is accommodated in the corresponding bearing accommodation zone. Each rear bearing support portion 82 contacts a whole peripheral surface of the corresponding one of the rear bearings 32, 33 so as to support the rear bearing 32, 33.
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A portion of the lower housing member 10 between the rotors 44, 49 and the first sealing members 34 (see
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An electric motor M is attached to the gear housing 5. A motor shaft Ml extending from the electric motor M is connected to the drive shaft 3 via a joint 8, which is a shaft joint. Therefore, when the electric motor M rotates the drive shaft 3, the driven shaft 4 is rotated synchronously with the drive shaft 3. As a result, each of the rotors 40 to 49 is rotated and fluid (gas) in the pump chambers 70 to 74 is transferred with pressure to the exhaust gas treatment apparatus 29 via the discharge port 14, the connection muffler 15 and the discharge mechanism 16.
Next, an assembling method of the Roots pump 1 is explained.
The drive shaft 3 having the drive rotors 40 to 44 and the driven shaft 4 having the driven rotors 45 to 49 are assembled to the lower housing member from above. Each of the rotors 40 to 49 is arranged between the lower wall pieces 11. The drive shaft 3 and the driven shaft 4 pass through the shaft insertion portions 111c to be accommodated in the semicircular portions 111b.
Then, the first sealing members 34, the second sealing members 35, and the bearings 32, 33 are moved along the axes P3, P4 from the rear side of the lower housing member 10 to be attached to the drive shaft 3 and the driven shaft 4, respectively (see
Next, clearances between the drive rotors 40 to 44 and the driven rotors 45 to 49 are measured and adjusted. One of the drive rotors 40 to 44 and one of the driven rotors 45 to 49 are selected. The clearance between each selected rotor and the corresponding lower wall piece 11 is measured by a clearance gauge to adjust the clearance. Measurement and adjustment of the clearance is repeated until an appropriate clearance is obtained. Since the drive rotors 40 to 44 are engaged with the drive shaft 3 and the driven rotors 45 to 49 are engaged with the driven shaft 4, the clearance between each of the other rotors and the corresponding lower wall piece 11 becomes an appropriate size when the clearance between each of the selected rotors and the corresponding lower wall piece 11 is adjusted to be an appropriate size.
After the clearances are adjusted, a fastener such as a C clip or a snap ring (not shown) is attached to an end surface of each of the rear bearings 32, 33 to determine the positions of the rear bearings 32, 33, the drive shaft 3, and the driven shaft 4 with respect to the axes P3, P4.
Then, one pair of the rotors are selected from the drive rotors 40 to 44 and the driven rotors 45 to 49 and the phase difference between the selected rotors is adjusted. Since the drive rotors 40 to 44 are arranged integrally with the drive shaft 3, the phase difference between the other pairs of rotors is simultaneously adjusted when the phase difference between the selected pair of rotors is adjusted.
Then, the drive gear 6 is engaged with the rear drive portion 3a and the driven gear 7 is engaged with the rear driven portion 4a such that the drive gear 6 is engaged with the driven gear 7. At this time, the upward force may act on the bearings 30 to 33. However, the rear lower support portions 13 and the front lower support portions 17 suppress the bearings 30 to 33 from being lifted from the lower housing member 10.
Then, the upper housing member 20 is joined to the lower housing member 10 by bolts. That is, the bolts (not shown) are inserted through the insertion holes (not shown) of the upper housing member 20 to screw the bolts to screw holes (not shown) formed in the lower housing member 10. Then, the rear drive portion 3a is connected to the motor shaft Ml via the joint 8. Accordingly, the assembling operation of the Roots pump 1 is completed.
The first embodiment has driven advantages.
(1) The opening edges 13a of each rear lower support portion 13 are located above the centers P1 of the rear bearings 32, 33. The rear opening width T1 of each rear lower support portion 13 is smaller than the diameter D1 of the rear bearings 32, 33. The opening edges of each front lower support portion 17 are also located above the centers of the front bearings 30, 31, and the opening width of each front lower support portion 17 is smaller than the diameter of the front bearings 30, 31.
Therefore, in a state where the drive shaft 3, the driven shaft 4, and the bearings 30 to 33 are mounted to the lower housing member 10, the opening edges 13a of the rear lower support portions 13 suppress the rear bearings 32, 33 from moving upward. Similarly, the opening edges of the front lower support portions 17 suppress the front bearings. 30, 31 from moving upward. Therefore, the bearings 30 to 33 are suppressed from being separated from the lower housing member 10. In other words, the upper housing member 20 is prevented from being assembled to the lower housing member 10 in a state where the bearings 30 to 33 are separated from the lower support portions 13, 17. As a result, the phase difference between the two of the rotors 40 to 49 that are engaged to each other is prevented from being adjusted in a state where the bearings 30 to 33 are separated from the lower support portions 13, 17. In other words, the upper housing member 20 is prevented from being assembled to the lower housing member 10 in a state where the phase difference between the two of the rotors 40 to 49 is offset. Since the unnecessary movement of the bearings 30 to 33 is prevented, the adjusted clearance between each of the rotors 40 to 49 and the lower wall piece 11 is prevented from being changed.
(2) The drive shaft 3, the driven shaft 4, the bearings 30 to 33, and the rotors 40 to 49 are exposed to the outside from the lower joint surface 10a in a state where they are mounted to the lower housing member 10 (see
(3) The whole area of the lower joint surface 10a, which contacts the upper housing member 20 is positioned in a single plane. Therefore, steps do not need to be formed on the lower joint surface 10a of the lower housing member 10. This permits the housing 2 to be manufactured easily.
(4) For example, when the lower joint surface 10a has steps, the upper joint surface 20a is joined to the lower joint surface 10a after the steps corresponding to the lower joint surface 10a are formed. If the lower joint surface 10a and the upper joint surface 20a have a dimensional tolerance, a space is likely to be created at the joint portion 50 between the lower joint surface 10a and the upper joint surface 20a. This may deteriorate the sealing property of the joint portion 50. However, since the lower joint surface 10a of the present embodiment is entirely flat, the upper joint surface 20a contacts the lower joint surface 10a without a gap. This improves the sealing property of the joint portion 50.
(5) The rear opening width T1 of each rear lower support portion 13 with respect to the width direction of the Roots pump 1 is set to be smaller than the diameter Dl of the rear bearings 32, 33. Further, the rear opening width T1 is set to be greater than the diameter (D2) of the portions of the drive shaft 3 and the driven shaft 4 that are supported by the rear bearing 32, 33 (D2<T1<D1). Similarly, the opening width of each front lower support portion 17 with respect to the width direction of the Roots pump 1 is set to be smaller than the diameter of the front bearings 30, 31 and is set to be greater than the diameter of the portions of the drive shaft 3 and the driven shaft 4 that are supported by the front bearings 30, 31. As a result, the bearings 30 to 33 are suppressed from being separated from the lower housing member 10. Further, the drive shaft 3 and the driven shaft 4 can be assembled to the lower housing member 10 from above.
(6) The Roots pump 1 has the drive shaft 3 and the driven shaft 4. The drive shaft 3 and the driven shaft 4 are rotated synchronously with each other by the meshing of the drive gear 6 and the driven gear 7, which are timing gears. When the drive gear 6 is meshed with the driven gear 7, the rear bearings 32, 33 might be separated from the lower housing member 10. However, since the opening edges 13a of the rear lower support portions 13 suppress the rear bearings 32, 33 from moving upward, the rear bearings 32, 33 are reliably suppressed from being separated.
(7) Each lower shaft accommodation portion 11a has the shaft insertion portion 111c. The accommodation opening width T3 of the shaft insertion portion 111c is set to be greater than the diameter (D3) of the portions of the drive shaft 3 and the driven shaft 4 that are accommodated in the lower shaft accommodation portions 11a. Therefore, the drive shaft 3 and the driven shaft 4 can be assembled to the lower housing member 10 from above by inserting the drive shaft 3 and the driven shaft 4 into the lower shaft accommodation portions 11a. Accordingly, the drive shaft 3 and the driven shaft 4 are easily mounted to the lower housing member 10.
Next, a second embodiment of the present invention will be explained with reference to
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The rear opening width T5 with respect to the width direction of the Roots pump 1 is set to be greater than the diameter (D5) of the portions of the drive shaft 3 and the driven shaft 4 that are arranged in the rear seal accommodation portion 80. That is, the rear opening width T5, which is the width between two opening edges 12a, is greater than the diameter D5. The diameter (D5) of the portion of the drive shaft 3 and the driven shaft 4 that is arranged in the rear seal accommodation portion 80 can be set to be smaller than the diameter D3 or D2 of the first embodiment.
Each shaft insertion portion 12b is defined between the corresponding pair of the opening edges 12a. The drive shaft 3 and the driven shaft 4 can be inserted to the rear lower seal accommodation portions 12 from above by passing through the shaft insertion portions 12b. A cylindrical rear sealing member 90 is accommodated in each rear lower seal accommodation portion 12. The rear sealing members 90 are attached to the drive shaft 3 and the driven shaft 4. Each rear sealing member 90 seals a space between the drive shaft 3 or the driven shaft 4 and the corresponding rear seal accommodation portion 80.
The inner surface of each rear upper seal accommodation portion 22 is formed in an arc as seen from the front side. Each rear upper seal accommodation portion 22 is formed in an arc so as to cover the peripheral surface of the rear sealing member 90 that protrudes upward from the lower joint surface 10a. The opening width T6 of the rear upper seal accommodation portion 22 is set to be the same as the rear opening width T5.
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Two rear seal rings 93 are arranged on the outer peripheral surface of each rear sealing member 90 at a portion close to the pump chamber 74. The rear seal rings 93 seal a space between the inner peripheral surface of each rear seal accommodation portion 80 and the outer peripheral surface of the corresponding rear sealing member 90.
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Each front lower seal accommodation portion 86 has an arc having an angle greater than 180 degrees. A shaft insertion portion 86b is defined between each facing pair of the opening edges 86a. The drive shaft 3 and the driven shaft 4 pass through the shaft insertion portions 86b to be inserted to the lower seal accommodation portions 86 from above. Each front lower seal accommodation portion 86 accommodates the cylindrical front sealing member 100.
Each front upper seal accommodation portion 87 is formed in an arc along the peripheral surface of the front sealing member 100. The opening width T8 of each front upper seal accommodation portion 87 is set to be the same as the front opening width T7.
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Next, an assembling method of the Roots pump 1 according to the second embodiment will be explained.
The drive shaft 3 having the drive rotors 40 to 44 and the driven shaft 4 having the driven rotors 45 to 49 are inserted to the lower housing member 10 from above. In this state, the rear sealing members 90, the oil slingers 94, the shims 95, and the rear bearings 32, 33 are moved along the axes P3, P4 from the rear side of the lower housing member 10 in this order to be attached to the drive shaft 3 and the driven shaft 4. The rear sealing members 90 are closely fitted to the drive shaft 3 and the driven shaft 4 so as to be rotated integrally therewith. Then, the rear bearings 32, 33 are inserted to the rear lower support portion 13. The rear bearings 32, 33 contact the step portions 10d formed between the rear lower seal accommodation portions 12 and the rear lower support portions 13.
The front sealing member 100 are attached to the drive shaft 3 and the driven shaft 4 from the front side of the lower housing member 10. The front sealing members 100 are closely fitted to the drive shaft 3 and the driven shaft 4 so as to be rotated integrally therewith. The front bearings 30, 31 are inserted to the front lower support portions 17. The front bearings 30, 31 contact the front sealing members 100.
Next, the clearance between each of the rotors 40 to 49 and the corresponding lower wall piece 11 is measured and adjusted to an appropriate size. Then, the shims 95 are adjusted. Thereafter, the drive gear 6 and the driven gear 7 are engaged with the drive shaft 3 and the driven shaft 4 such that the upper housing member 20 is joined to the lower housing member 10.
The second embodiment has the following advantage in addition to the advantages (1) to (7) of the first embodiment.
(8) The diameters (D5, D7) of the drive shaft 3 and the driven shaft 4 are set to be smaller than the opening widths T5, T7 of the lower seal accommodation portions 12, 86 such that the drive shaft 3 and the driven shaft 4 can be inserted to the seal accommodation portions 80, 84 from above. The height of the opening edges 12a, 86a of the lower seal accommodation portions 12, 86 is set to be higher than the centers of the sealing members 90, 100. Each cylindrical sealing member 90, 100 seals the space between the inner peripheral surface of the seal accommodation portion 80, 84 and the peripheral surface of the drive shaft 3 or the driven shaft 4. Therefore, the straight portions (see 111a) for inserting the drive shaft 3 and the driven shaft 4 are deleted from the corresponding portion of the lower housing member 10 between the front bearing 30 and the drive rotor 40, between the front bearing 31 and the driven rotor 45, between the rear bearing 32 and the drive rotor 44, and between the rear bearing 33 and the driven rotor 49. Accordingly, the space between one of the peripheral surfaces of the first rotary shaft and the driven shaft 4, and the corresponding one of the inner peripheral surfaces of the seal accommodation portions 80, 84 is easily sealed.
Each of the above embodiments is not limited thereto but may be modified as follows.
The height of the uppermost portion of the lower housing member 10, that is, the height of the opening edges 13a of each lower support portion 13, 17 may be at any position as long as it is above the center P1 of the bearing 30, 33. The opening width T1 of each lower support portion 13, 17 needs to be greater than the diameter (D2) of the drive shaft 3 and the driven shaft 4. For example, the height of the opening edges 13a may be set above or below the center between the center P1 of the rear bearings 32, 33 and the top portion Q1 of the rear bearings 32, 33.
The height of the portion of the lower housing member 10 other than the opening edges 13a of the lower support portions 13, 17 may be below the centers of the front bearings 30, 31 or the centers P1 of the rear bearings 32, 33. That is, only the opening edges 13a of the lower support portion 13, 17 may be set to be above the centers P1 of the bearings 30 to 33. The height of the upper surface of the lower wall piece 11 may be set to be the same as the axes P3, P4. By extending the upper wall pieces 21 to contact the lower wall piece 11, fluid leakage between the adjacent pump chambers 70 to 74 is suppressed. The height of only the opening edges of each lower shaft accommodation portion 11a, which are the upper ends of the lower shaft accommodation portion 11a, may be set to be the same as the axes P3, P4. That is, the height of only the portion of the lower joint surface 10a corresponding to the lower shaft accommodation portions 11a may be set to be the same as the axes P3, P4. In this case, the space between each lower shaft accommodation portion 11a and the drive shaft 3 or the driven shaft 4 may be reduced. This easily suppresses fluid that is transported by the rotors 40 to 49 from passing through the space between the lower shaft accommodation portions 11a and the peripheral surface of the drive shaft 3 or the driven shaft 4 and leaking therefrom.
As long as the rear opening width T1 of the rear lower support portions 13 is smaller than the diameter D1 of the rear bearings 32, 33, the other portion of the rear bearing support portions 82 may be deformed so as to correspond to the outer shape of the rear bearings 32, 33. For example, the curvature of the arc of the rear upper support portions 23 may be set to be smaller than that of the arc of the rear lower support portions 13.
The size and the shape of each pump chamber 70 to 74 may be changed according to the size and the shape of each rotor 40 to 49.
The present invention may be applied to a fluid machine other than the Roots pump 1, for example, a screw pump or a claw pump. The fluid machine may be any machine that transports fluid by rotation of the drive shaft 3 and the driven shaft 4 having the rotors 40 to 49.
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The sealing members 90, 100 do not need to be rotated integrally with the drive shaft 3 or the driven shaft 4, but may be fixed to the inner peripheral surfaces of the seal accommodation portions 80, 84, respectively.
The housing 2 does not need to have two rotary shafts, but may have only one rotary shaft. In this case, an upward force acts on the bearing when the bearing is press-fitted to the rear lower support portion 13. The rear lower support portion 13 suppresses the bearing from being separated.
The number of the pump chambers in the housing 2 may be changed and may be one.
Number | Date | Country | Kind |
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2006-196743 | Jul 2006 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP2007/064221 | 7/19/2007 | WO | 00 | 1/15/2009 |