Information
-
Patent Grant
-
6652250
-
Patent Number
6,652,250
-
Date Filed
Tuesday, October 16, 200123 years ago
-
Date Issued
Tuesday, November 25, 200321 years ago
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Inventors
-
Original Assignees
-
Examiners
- Freay; Charles G.
- Sayoc; Emmanuel
Agents
- Oblon, Spivak, McClelland, Maier & Neustadt, P.C.
-
CPC
-
US Classifications
Field of Search
US
- 417 357
- 417 365
- 417 4231
- 417 42315
- 417 42311
- 417 42314
- 417 4104
- 412 42312
- 412 4241
- 418 2011
- 418 2013
- 418 2012
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International Classifications
-
Abstract
A screw compressor 1 comprises a screw compressor body 2 having a pair of female and male screw rotors 21 meshed with each other encased in a rotor casing 22, and a motor casing 4 having a motor 3 for driving a male rotor 21b of the screw rotor 21 encased therein. The screw compressor body 2 and the motor casing 4 are connected integrally. The male rotor 21b and the motor 3 are connected by a common rotor shaft 23. In the common rotor shaft 23, the counter motor 3 side is supported by a rolling bearing and a projecting end of the motor 3 is supported by a rolling bearing 7 on the motor side, and a portion between the motor 3 and the screw rotor 21 is supported by an intermediate rolling bearing 6.
Description
BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates to a technical field of a screw compressor.
2. Description of the Related Art
A conventional screw compressor heretofore known, as shown in
FIG. 6
, has the constitution in which a male rotor and a motor out of a pair of female and male screw rotors have a mutual shaft in common. In this case, since a coupling for connecting a shaft of the screw rotor and a shaft of the motor is unnecessary, it is economically advantageous. However, despite that the weight of a rotor of the motor is heavy, a rotor shaft for supporting the rotor is supported by way of only the screw rotor side, and therefore, the critical speed (rotational speed when the bending natural frequency in the flexing direction of a rotational shaft coincides with the rotational frequency) of the screw rotor is low. This screw compressor is applied to an oil cooling type screw compressor. In that case, since the compressor is operated at the low speed rotation of about 3600 rpm, it can be always operated at a rotational speed less than the critical speed, the possibility posing a problem being low.
Incidentally, a consideration is made that the screw compressor is applied to an oil free screw compressor. Then, the possibility of operation at the high speed rotation about 20000 rpm, that is, the rotational speed in excess of the critical speed, increases. That is, there is the time exceeding the critical speed. Then, as shown in
FIG. 7
of an explanatory view of a relationship between the rotational frequency when passing through the critical speed (at the start time) and the amplitude, the amplitude of the rotor shaft increases directly after exceeding the critical speed, increasing the possibility that an inconvenience occurs in contact of screw rotors. Therefore, it has been difficult to employ the conventional screw compressor for the oil free screw compressor.
Incidentally, there is contemplated the measures that as shown in
FIG. 7
, since the amplitude of the rotor shaft gradually becomes small as assuming the higher speed rotation than the critical speed, the speed increasing acceleration of the rotational frequency of the rotor is increased when exceeding the critical speed to allow the rotational frequency at which the amplitude of the rotor shaft increases to pass through in a short period of time. However, this has a limit naturally, and is not always practical.
SUMMARY OF THE INVENTION
It is an object of the present invention to provide a screw compressor capable of being operated at a speed less than the critical speed while raising the critical speed than that of prior art. A further object of the present invention is to provide a screw compressor capable of being applied to an oil free screw compressor, without occurrence of inconvenience of the contact of screw rotors.
The screw compressor according to the present invention comprises a compressor body comprising a pair of female and male screw rotors meshed with each other, a rotor casing for encasing the screw rotors, a motor for driving one out of the screw rotors, and a motor casing for encasing the motor and connected integral with the rotor casing (of the compressor body). One out of the screw rotors and the motor have a shaft in common. Opposite ends of the shaft are supported by bearings. A portion between the motor and the screw rotor is supported by an intermediate bearing.
Preferably, a seal part is peripherally provided between a bearing located on the end side of the shaft on the motor side and the motor, and between the motor and the screw rotor.
Further, preferably, compression gas of higher pressure than that acting on the seal part between the motor and the screw rotor is introduced into the motor casing.
Further, a bearing for supporting opposite ends of the shaft and the intermediate bearing may comprise a rolling bearing.
Further, a motor may be disposed on the suction side of the screw rotor, and a pressure receiving portion at which generates the force in a direction from the motor toward the screw rotor may be provided on the end on the motor side of the shaft.
Further, the pressure receiving portion may comprise a piston of a cylinder portion.
Furthermore, a pressure receiving portion may be provided in close contact with a piston member provided, in the periphery of an outer race of a bearing, integral with the outer race and capable of being moved forward and backward in the longitudinal direction of an output shaft, and the piston member and a screw rotor with respect to the piston member may comprise a diaphragm for partitioning a space portion on the opposite side.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1
is an explanatory view of a screw compressor according to an embodiment of the present invention;
FIG. 2
is an explanatory view of a seal portion in the embodiment of the present invention;
FIG. 3
is an explanatory view of a seal portion in the embodiment of the present invention;
FIG. 4
is an explanatory view of a screw compressor in the embodiment of the present invention;
FIG. 5
is an explanatory view of a screw compressor in the embodiment of the present invention; and
FIG. 6
is an explanatory view of a relationship between the rotational frequency at the time of passing a critical speed (at the start time) and the amplitude.
FIG. 7
is an explanatory view of a relationship between the rotational frequency at the time of passing a critical speed (at the start time) and the amplitude.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS
The screw compressor according to an embodiment of the present invention will be described hereinafter with reference to
FIG. 1
, an explanatory view of a plan sectional constitution, and
FIGS. 2 and 3
, respectively, explanatory views of a constitution of a seal portion in order.
Reference numeral
1
shown in
FIG. 1
denotes a screw compressor according to an embodiment of the present invention. This screw compressor is a so-called oil free screw compressor. The screw compressor
1
comprises a screw rotor
21
comprising a female rotor
21
a
having shaft parts of opposite ends supported by bearings and a male rotor
21
b
meshed with the female rotor
21
a
, and a screw compressor body
2
comprising a rotor casing
22
having the screw rotor
21
encased therein. A motor casing
4
having a motor
3
encased therein comprising a rotor
31
and a stator
32
is integrally mounted on one side of the screw compressor
2
. A rotor shaft of the male rotor
21
b
out of the pair of female and male screw rotors
21
is in common with a rotor shaft of the motor
3
.
On the counter motor
3
side of the screw rotor
21
of the rotor casing
22
is disposed a rotor side rolling bearing
5
comprising a combination of three angular contact bearings and one roller bearing. On the motor
3
side is disposed an intermediate rolling bearing
6
comprising a needle roller bearing which is an intermediate bearing. On the counter screw rotor
21
of the motor
3
of the motor casing
4
is disposed a motor side rolling bearing
7
comprising a ball bearing. All of the rotor side rolling bearing
5
, the intermediate rolling bearing
6
and the motor side rolling bearing
7
are fitted in a bearing cage with which a lubricating oil supply passage is communicated.
A projecting end from the male rotor
21
b
of the common rotor shaft
23
which is a common shaft of the male rotor
21
b
and the motor
3
is fitted in the rotor side rolling bearing
5
. A portion between the male rotor
21
and the motor
3
of the common rotor
23
is fitted in the intermediate rolling bearing
6
. The projecting end from the motor
3
is fitted in the motor side rolling bearing
7
whereby the common rotor shaft
23
is supported at three points. Because, if the constitution is made such that the common rotor shaft
23
is supported at three points as described, the critical speed of the common rotor shaft
23
can be enhanced positively.
Seal parts
8
are respectively peripherally provided between the intermediate rolling bearing
6
and the motor
3
, of the common rotor shaft
23
, and between the intermediate rolling bearing
6
side, the motor side rolling bearing
7
and the motor
3
. As these seal parts
8
, there can be employed, for example, a carbon seal, a mechanical seal, an oil seal, and in addition, a labyrinth seal as shown in
FIG. 2
, and a seal of the type provided with a thrower disk
8
a
which blows away oil by the centrifugal force as shown in FIG.
3
.
Further, a compressed air discharge port
22
a
for discharging a leaking portion of compressed air which is a compressed gas compressed by the screw rotor
21
is provided in the rotor casing
3
, and an air introducing pipeline not shown is communicated with an air inlet
3
a
provided in the motor casing
4
from the compressed air discharge port
22
a
. That is, compressed air discharged out of the compressed air discharge port
22
a
is introduced into the motor casing
3
through the air inlet
3
a.
The reason why compressed air is introduced into the motor casing
3
, in addition to the seal part
8
, is to aim at preventing a leakage of lubricating oil to the motor casing
4
supplied from the lubricating oil supply passage to the bearing cage more positively. That is, since by the provision of such arrangement as described, contact of the motor
3
of lubricating oil with the rotor
31
is prevented more positively, it is possible to avoid the possibility of the insulating breakage of the rotor
31
due to carbonization of lubricating oil. A shaft seal device is interposed between the screw rotor
21
and the rotor side rolling bearing
5
, and between the screw rotor
21
and the intermediate rolling bearing
6
.
The projecting end from the motor
3
of the common rotor shaft
23
which is a common shaft of the male rotor
21
b
and the motor
3
is fitted in the motor side rolling bearing
7
to thereby provide restriction. Therefore, this is not the constitution of a cantilever support which is a support by way of only the screw rotor side unlike the common rotor shaft in prior art, and the natural frequency of the common rotor shaft
23
increases. There has been also proposed a screw compressor having the constitution which is not provided with an intermediate rolling bearing, but as compared therewith, the screw compressor
1
according to the present embodiment is able to further enhance the natural frequency of the common rotor shaft. By the constitution in which the common rotor is supported at three points, the flexure of the common rotor shaft can be suppressed, and the contact between the rotors can be prevented.
Accordingly, the critical speed increases so that for example, even if the screw compressor
1
is an oil screw compressor, operation within the critical speed becomes enabled, thus providing the excellent effect capable of eliminating possible occurrence of inconvenience in contact between the female rotor
21
a
and the male rotor
21
b
of the screw rotor
21
.
Further, while in the screw compressor
1
according to the present embodiment, the common rotor shaft
23
is supported at three points, i.e., the rotor side rolling bearing
5
, the intermediate rolling bearing
6
and the motor side rolling bearing
7
, it is noted that generally, a rolling bearing is small in clearance in the bearing as compared with a slide bearing. Therefore, a clearance between a pair of female and male screw rotors
21
can be also made small, thus providing the effect capable of further enhancing the performance as the screw compressor
1
.
The screw compressor according to a further embodiment will be described hereinafter with reference to
FIGS. 4 and 5
.
FIG. 4
shows an oil free screw compressor
1
A according to an embodiment of the present invention, separately from one that described above. The oil free screw compressor
1
A comprises a compressor body
2
, and a motor
3
A which is a drive part having a motor casing
4
connected integral with a rotor casing
22
of the compressor body
2
. A pair of female and male screw rotors meshed with each other are rotatably encased in a rotor chamber
15
in the rotor casing
22
. In
FIG. 4
, only the male rotor
21
b
on the drive side is shown.
The rotor casing
22
is formed with a suction port
17
opened to one end of the rotor chamber
15
, and a discharge port
18
opened to the other end. A shaft
23
d
extended on the discharge side of the male rotor
21
b
is supported by bearings
5
a
and
5
b
, and shaft seal parts
24
,
25
are provided between the bearing
5
a
and the male rotor
21
b
and between the bearings
5
a
,
5
b
, respectively. Further, a synchronous gear
26
is provided on the end of the shaft
23
d
. The synchronous gear
26
is meshed with a synchronous gear provided on the end of a shaft of the other screw rotor not shown, that is, the female rotor
21
a
to function to transmit the rotating force to the female rotor
21
a
. Further, a shaft
23
s
extended on the suction side of the male rotor
21
b
is supported by a bearing
28
, and shaft seal parts
51
,
52
are provided on both sides of the bearing
28
.
The motor
3
A is arranged on the suction side of the compressor body
2
, an output shaft
34
extending through the center part of a rotor
31
is integrally formed on the same shaft as the shaft
23
s
extended on the suction side of the male rotor
21
b
, that is, the motor
3
A and the male rotor
21
b
have a shaft in common. That is, the shafts
23
d
,
23
s
and the output shaft
34
form an integral rotor shaft
23
. The bearing
28
acts to support one end of the output shaft
34
. Further, the side opposite to the bearing
28
of the output shaft
34
is supported on the bearing
35
, and a shaft seal part
36
is provided between the bearing
35
and the rotor
34
. Further, on the other end of the output shaft
34
extending through the bearing
35
, that is, the end opposite to the male rotor
21
b
of the output shaft
34
is provided a piston
41
as a pressure receiving part which generates the force caused by fluid pressure in the direction from the other end to the one end, that is, in the direction from the motor
3
A to the male rotor
21
b.
That is, there is provided a cylinder part
44
into which is inserted a piston
41
capable of being moved forward and backward in a space
43
to which is supplied fluid pressed as indicated by arrow I from an inlet/outlet
42
formed in the motor casing
4
on the end side of the other end. Counter thrust acts on the shafts
23
d
and
23
s
through the output shaft
34
from the piston
41
. Preferably, the pressed fluid is oil.
Since as described above, in the oil free screw compressor
1
A, the motor
3
A is provided on the suction side of the male rotor
21
b
, gas is not blown through the motor
3
A from the rotor chamber
15
. There are not brought forth scattering of oil to the rotor
31
, inferior insulation at the rotor
31
, and lowering of performance due to the stirring loss of oil, which occur in a case where gas is blown through, thus enabling relieving the force in the thrust direction acting on the shafts
23
b
,
23
s
of the male rotor
21
b
to prolong the service life of bearings.
FIG. 5
shows an oil free screw compressor
1
B according to an embodiment of the present invention, separately from one that described above. The parts common to the oil free screw compressor
1
A shown in
FIG. 4
are indicated by the same numerals, explanation of which is omitted.
In the oil free screw compressor
1
B, a diaphragm
45
having flexibility is provided on the other end of the side opposite to male rotor
21
b
side of the output shaft
34
, as a pressure receiving part which generates the force caused by fluid pressure in the direction from the other end toward one end on the male rotor
21
b
side.
That is, there is provided the diaphragm
45
, in the periphery of an outer race of he bearing
35
disposed on the other end of the output shaft
34
, in close contact with a piston member
46
provided capable of being moved forward and backward in a longitudinal direction extending through the end surface of the motor casing
4
, to airtightly partition between the piston member
46
and the space
43
opposite to the male rotor
21
b
with respect to the piston member
46
. The diaphragm
45
receives pressure in the space
43
to act the counter thrust on the output shaft
34
through the piston member
46
and the bearing
35
to transmit the counter thrust to the shafts
23
d
,
23
s
. Preferably, the fluid pressed is compression gas.
As a result, there are not brought forth scattering of oil to the rotor
31
, inferior insulation at the rotor
31
, and lowering of performance due to the stirring loss of oil, which occur in a case where gas is blown through, thus enabling relieving the force in the thrust direction acting on the shafts
23
b
,
23
s
of the male rotor
21
b
to prolong the service life of bearings, similar to the case where the piston
41
described above is provided.
Claims
- 1. A screw compressor comprising:a compressor body having a pair of female and male screw rotors meshed with each other, said compressor body having a rotor casing for encasing said screw rotors; a motor for driving one of said screw rotors; a motor casing connected integrally with said rotor casing, said motor casing encasing said motor; and a shaft which is common to one of said screw rotors and said motor, opposite ends of said shaft being supported by bearings, a portion between said motor and said screw rotor being supported by an intermediate bearing.
- 2. The screw compressor according to claim 1, further comprising seal parts provided at the periphery of said shaft between said motor and one of said bearings positioned on the motor end of said shaft, and between said motor and said screw rotor, respectively.
- 3. The screw compressor according to claim 2, further comprising means for introducing into said motor casing compressed gas higher in pressure than pressure acting on the seal part between said motor and said screw rotor.
- 4. The screw compressor according to claim 1, wherein a bearing for supporting opposite ends of said shaft and said intermediate bearing comprise a rolling bearing.
- 5. The screw compressor according to claim 1, further comprising a motor disposed on the suction side of said screw rotor, and a pressure receiving part which generates the force in the direction from said motor toward said screw rotor on the end on the motor side of said shaft.
- 6. The screw compressor according to claim 5, wherein said pressure receiving part comprises a piston of a cylinder part.
- 7. The screw compressor according to claim 5, wherein said pressure receiving part comprises a diaphragm provided, in the periphery of an outer race of a bearing, in close contact with a piston member provided integral with said outer race and capable of being moved forward and backward in a longitudinal direction of said output shaft, to partition said piston member and a space part opposite to said screw rotor with respect to said piston member.
Priority Claims (2)
Number |
Date |
Country |
Kind |
2000-315159 |
Oct 2000 |
JP |
|
2000-382035 |
Dec 2000 |
JP |
|
US Referenced Citations (9)
Foreign Referenced Citations (2)
Number |
Date |
Country |
10103265 |
Apr 1998 |
JP |
11-351168 |
Dec 1999 |
JP |