This U.S. National stage application claims priority under 35 U.S.C. §119(a) to Japanese Patent Application No. 2006-299227, filed in Japan on Nov. 2, 2006, the entire contents of which are hereby incorporated herein by reference.
The present invention relates to a compressor to be used in, for example, air conditioners, refrigerators and the like.
Conventionally, there has been provided a compressor including a disc-shaped screw rotor which rotates about a center axis and which has, in its end face in a center-axis direction, a plurality of spirally extending groove portions radially outward from the center axis, and a gate rotor which rotates about a center axis and which has a plurality of tooth portions arrayed circumferentially on its outer circumference, the groove portions of the screw rotor and the tooth portions of the gate rotor being engaged with each other to form a compression chamber (see JP 60-10161 B).
That is, this compressor is a so-called PP type single screw compressor. The term “PP type” means that the screw rotor is formed into a plate-like shape and moreover the gate rotor is formed into a plate-like shape.
Then, as viewed in a direction orthogonal to the screw rotor center axis and the gate rotor center axis, all the tooth portions of the gate rotor overlap with the screw rotor center axis. That is, the tooth portions of the gate rotor are engaged with the groove portions of the screw rotor along the radial direction of the screw rotor.
With a view to preventing interferences between the screw rotor and the gate rotor, side faces of the gate rotor tooth portions are given a maximum angle and a minimum angle each of which is formed by a gate rotor tooth-portion side face and a screw rotor groove wall surface on a plane which orthogonally intersects with the gate rotor plane and which contains a rotational direction of a tooth center line extending radial direction of the gate rotor (hereinafter, angles formed between the maximum angle and the minimum angle will be referred to as edge angles of the gate rotor; see edge angles δ1, δ2 of
However, with the conventional compressor described above, since all the tooth portions of the gate rotor are aligned with the screw rotor center axis as viewed in a direction orthogonal to the screw rotor center axis and the gate rotor center axis, angles formed by side faces of the screw rotor groove against side faces of the gate rotor tooth portions on the plane orthogonally intersecting with the gate rotor plane and containing the rotational direction of the gate rotor tooth center line involves a larger difference between a maximum value and a minimum value.
As a result of this, edge angles of gate rotor seal portions to be engaged with the side faces of the screw rotor groove portion become acute, so that a blow hole (leak clearance) present at an engagement portion between the screw rotor groove portion and the gate rotor tooth portion becomes larger. This would result in a lowered compression efficiency.
Accordingly, an object of the present invention is to provide a compressor in which the blow hole is made smaller so as to improve the compression efficiency.
In order to achieve the above object, there is provided a compressor comprising: a disc-shaped screw rotor which rotates about a center axis and which has, in at least one end face thereof in a direction along the center axis, a plurality of spirally extending groove portions radially outward from the center axis; and a gate rotor which rotates about a center axis and which has a plurality of tooth portions arrayed circumferentially on its outer circumference, the groove portions of the screw rotor and the tooth portions of the gate rotor being engaged with each other to form a compression chamber, wherein
a variation width of an inclination angle to which a side face of a groove portion of the screw rotor to be in contact with the tooth portions of the gate rotor is inclined against a circumferential direction of the gate rotor, the variation being over a range from radially outer side to inner side of the screw rotor,
is made smaller than
a variation width resulting when all the tooth portions of the gate rotor overlap with a plane containing the screw rotor center axis.
With such a compressor, the variation width of the inclination angle to which the side face of the groove portion of the screw rotor to be in contact with the tooth portions of the gate rotor is inclined against the circumferential direction of the gate rotor, the variation being over a range from radially outer side to inner side of the screw rotor, is made smaller than a variation width resulting when all the tooth portions of the gate rotor overlap with a plane containing the screw rotor center axis. Therefore, edge angles of the seal portions of the gate rotor to be engaged with side faces of the groove portion of the screw rotor can be made obtuse, so that the blow holes (leak clearances) present at engagement portions between the groove portion of the screw rotor and the tooth portions of the gate rotor can be made smaller, allowing the compression efficiency to be improved. Besides, wear of the seal portions of the gate rotor can be reduced, allowing an improvement in durability to be achieved.
Also, there is provided a compressor comprising: a disc-shaped screw rotor which rotates about a center axis and which has, in at least one end face thereof in a direction along the center axis, a plurality of spirally extending groove portions (10) radially outward from the center axis; and a gate rotor which rotates about a center axis and which has a plurality of tooth portions arrayed circumferentially on its outer circumference, the groove portions of the screw rotor and the tooth portions of the gate rotor being engaged with each other to form a compression chamber, wherein
with respect to a first plane containing the screw rotor center axis, a second plane which intersects orthogonally with the screw rotor center axis, and a third plane which intersects orthogonally with the first plane (S1) and the second plane,
the gate rotor center axis is on the third plane, and
at least one of all the tooth portions of the gate rotor does not overlap with the first plane as viewed in a direction orthogonal to the third plane.
With such a compressor, the gate rotor center axis is on the third plane, and at least one of all the tooth portions of the gate rotor does not overlap with the first plane as viewed in a direction orthogonal to the third plane. Therefore, the side face of the groove portion of the screw rotor to be in contact with the tooth portions of the gate rotor can be set at approximately 90° against the rotational direction of the gate rotor (i.e. circumferential direction of the gate rotor) in its portion to be in contact with the side face of the groove portion of the screw rotor. Thus, the variation width of an angle formed by the side face of the groove portion of the screw rotor (hereinafter, referred to as screw rotor groove inclination angle) against a plane orthogonally intersecting with the rotational direction of the gate rotor (the circumferential direction of the gate rotor) can be made smaller.
Therefore, edge angles of the seal portions of the gate rotor to be engaged with side faces of the groove portion of the screw rotor can be made obtuse, so that the blow holes (leak clearances) present at engagement portions between the groove portion of the screw rotor and the tooth portions of the gate rotor can be made smaller, allowing the compression efficiency to be improved. Besides, wear of the seal portions of the gate rotor can be reduced, allowing an improvement in durability to be achieved.
In accordance with one aspect of the present invention, as viewed in the direction orthogonal to the third plane, a distance from an intersection point between a gate rotor plane formed by the first plane side end face of every tooth portion of the gate rotor and the gate rotor center axis (2a) to the first plane is 0.05 to 0.4 time as large as an outer diameter of the tooth portion of the gate rotor.
With such a compressor in accordance with this aspect of the present invention, as viewed in the direction orthogonal to the third plane, a distance from an intersection point between a gate rotor plane formed by the first plane side end face of every tooth portion of the gate rotor and the gate rotor center axis to the first plane is 0.05 to 0.4 time as large as an outer diameter of the tooth portion of the gate rotor. Therefore, the variation width of the screw rotor groove inclination angle can be made even smaller.
In accordance with one aspect of the present invention, as viewed in the direction orthogonal to the third plane, the gate rotor center axis is inclined by 5° to 30° against the second plane so that a tooth portion of the gate rotor closer to the screw rotor becomes closer to the screw rotor center axis than a tooth portion of the gate rotor farther from the screw rotor.
With such a compressor, as viewed in the direction orthogonal to the third plane, the gate rotor center axis is inclined by 5° to 30° against the second plane so that a tooth portion of the gate rotor closer to the screw rotor becomes closer to the screw rotor center axis than a tooth portion of the gate rotor farther from the screw rotor. Therefore, the variation width of the screw rotor groove inclination angle can be made even smaller.
In accordance with one aspect of the present invention, as viewed in a direction orthogonal to the first plane, a distance between the gate rotor center axis and the screw rotor center axis is 0.7 to 1.2 times as large as an outer diameter of the gate rotor.
With such a compressor, as viewed in a direction orthogonal to the first plane, a distance L between the gate rotor center axis and the screw rotor center axis is 0.7 to 1.2 times as large as an outer diameter D of the gate rotor. Therefore, the distance L can be made smaller, allowing a downsizing to be achieved.
In accordance with one aspect of the present invention, seal portions of the tooth portions of the gate rotor to be in contact with the groove portions of the screw rotor are formed into a curved-surface shape.
With such a compressor, since the seal portions of the tooth portions of the gate rotor to be in contact with the groove portion of the screw rotor are formed into a curved-surface shape, leakage of the compressed fluid from engagement portions between the tooth portions of the gate rotor and the groove portion of the screw rotor can be reduced, so that the compression efficiency can be improved.
With a compressor in accordance with an embodiment of the present invention, the variation width of the inclination angle to which the side face of the groove portion of the screw rotor to be in contact with the tooth portions of the gate rotor is inclined against the circumferential direction of the gate rotor, the variation being over a range from radially outer side to inner side of the screw rotor, is made smaller than a variation width resulting when all the tooth portions of the gate rotor overlap with a plane containing the screw rotor center axis. Therefore, the blow holes can be made smaller, allowing the compression efficiency to be improved.
Also, with a compressor in accordance with an embodiment of the present invention, the gate rotor center axis is on the third plane, and at least one of all the tooth portions of the gate rotor does not overlap with the first plane as viewed in a direction orthogonal to the third plane. Therefore, the blow holes can be made smaller, allowing the compression efficiency to be improved.
Hereinbelow, the present invention will be described in detail by way of embodiment thereof illustrated in the accompanying drawings.
That is, this compressor is a so-called PP-type single screw compressor. The term ‘PP-type’ means that the screw rotor 1 is formed into a plate-like shape while the gate rotor 2 is formed into a plate-like shape. This compressor is to be used in, for example, air conditioners, refrigerators and the like.
The groove portions 10 are formed in each of two end faces of the screw rotor 1. The gate rotor 2 is provided two in number on each end face of the screw rotor 1. Then, as the screw rotor 1 rotates about the screw rotor center axis 1a along a direction indicated by an arrow, each gate rotor 2 subordinately rotates about the gate rotor center axis 2a along an arrow direction by mutual engagement of the groove portions 10 and the tooth portions 20.
On an end face of the screw rotor 1 are provided a plurality of thread ridges 12 spirally extending radially outward from the screw rotor center axis 1a, where the groove portions 10 are formed between neighboring ones of the thread ridges 12, 12. With one of the tooth portions 20 engaged with one of the groove portions 10, side faces (i.e. seal portions) of the tooth portion 20 come into contact with side faces 11 of the groove portion 10 to seal the compression chamber 30, while the tooth portion 20 is rotated by the side faces 11 of the groove portion 10.
On an end face of the screw rotor 1 is attached a casing (not shown) which has grooves that allow the gate rotors 2 to rotate. A space closed by the groove portion 10, the tooth portion 20 and the casing serves as the compression chamber 30.
In the casing is provided a suction port (not shown) communicating with the groove portions 10 on the outer peripheral side of the screw rotor 1. In the casing is also provided a discharge port (not shown) communicating with the groove portions 10 on the center side of the screw rotor 1.
Referring to action of the compressor, a fluid such as refrigerant gas introduced to the groove portion 10 through the suction port is compressed in the compression chamber 30 as the capacity of the compression chamber 30 is reduced by rotation of the screw rotor 1 and the gate rotor 2. Then, the compressed fluid is discharged through the discharge port.
As shown in the simplified front view of
The gate rotor center axis 2a is on the third plane S3. None of the tooth portions 20 of the gate rotor 2 overlaps with the first plane S1 as viewed in a direction orthogonal to the third plane S3.
As viewed in the direction orthogonal to the third plane S3, a distance d from an intersection point between a gate rotor plane SG formed by an first plane S1 side end face of every tooth portion 20 of the gate rotor 2 and the gate rotor center axis 2a to the first plane S1 (hereinafter, referred to as positional-shift distance d) is 0.05 to 0.4 time as large as an outer diameter D of the tooth portion 20 of the gate rotor 2 (0.05D≦d≦0.4D).
As viewed in the direction orthogonal to the third plane S3, the gate rotor center axis 2a is inclined against the second plane S2 so that a tooth portion 20 of the gate rotor 2 closer to the screw rotor 1 becomes closer to the screw rotor center axis 1a than a tooth portion 20 of the gate rotor 2 farther from the screw rotor 1. An inclination angle α of the gate rotor center axis 2a is 5°-30°. In this case, an engagement depth of the tooth portions 20 with the groove portions 10 is 0.2 time as large as an outer diameter D of the gate rotor 2.
As viewed in a direction orthogonal to the first plane S1, a distance L between the gate rotor center axis 2a and the screw rotor center axis 1a (hereinafter, referred to as axis-to-axis distance L) is 0.7 to 1.2 time as large as the outer diameter D of the gate rotor 2 (0.7D≦L≦1.2D).
In the gate rotor plane SG, an angle that a center line of the tooth portion 20 engaged with the groove portion 10 forms against a reference line parallel to the axial end face (second plane S2) of the screw rotor 1 is referred to as a gate rotor engagement angle γ, and the angle of the center line (an intermediate line between leading side and unleading side) of the tooth portion 20 is measured from the reference line on a side of engagement starting.
The enlarged plan view of
Next,
It is to be noted here that the screw rotor groove inclination angle β, as shown in
Also,
That is, in
Also,
That is, in
As shown in the enlarged sectional view of
That is, a leading-side seal portion 21a is formed at the leading-side side face 20a of the tooth portion 20, while an unleading-side seal portion 21b is formed at the unleading-side side face 20b of the tooth portion 20.
The screw rotor 1 moves along a downward-pointed arrow RS direction, while the gate rotor 2 moves along a leftward-pointed arrow RG direction.
At engagement portions between the groove portion 10 of the screw rotor 1 and the tooth portion 20 of the gate rotor 2, blow holes (leak clearances) 40, 50 shown by hatching are present.
More specifically, a leading-side blow hole 40 (shown by hatching) is present on an upstream side (compression chamber 30 side shown by hatching) of the leading-side seal portion 21a in the moving direction of the screw rotor 1, while an unleading-side blow hole 50 (shown by hatching) is present on an upstream side (the compression chamber 30 side) of the unleading-side seal portion 21b in the moving direction of the screw rotor 1.
The fluid compressed in the compression chamber 30 passes through the blow holes 40, 50 to leak outside the casing 3 (shown by imaginary line).
According to the compressor of the above-described constitution, since the gate rotor center axis 2a is present on the third plane S3 and since at least one of all the tooth portions 20 of the gate rotor 2 does not overlap with the first plane S1 as viewed in a direction orthogonal to the third plane S3, side faces 11 of a groove portion 10 of the screw rotor 1 to be in contact with the tooth portion 20 of the gate rotor 2 can be set at approximately 90° against the rotational direction (indicated by arrow RG) of the tooth portion 20 of the gate rotor 2 to be in contact with the side faces 11 of the groove portion 10 of the screw rotor 1 (i.e. against the circumferential direction of the gate rotor 2) as shown in
More specifically, in cases where the positional shift or inclination of the gate rotor 2 as in the present invention is not used (prior art), the changing width of the screw rotor groove inclination angle β during the course from suction to discharge becomes 16.0° at the leading-side side face 20a and 15.6° at the unleading-side side face 20b. In contrast to this, in a case where the positional shift or inclination of the gate rotor 2 of the invention is applied to a compressor whose configuration (gate rotor tooth number, screw rotor groove number, gate rotor diameter, axis-to-axis distance, gate rotor tooth width, and suction cut angle) is similar to that of the prior art, the results are 6.5° at that the leading-side side face 20a and 13.8° at the unleading-side side face 20b.
In other words, the variation width of the inclination angle of the side faces 11 of the groove portion 10 of the screw rotor 1 to be in contact with the tooth portion 20 of the gate rotor 2, the inclination being against the circumferential direction of the gate rotor 2 and the variation width measuring from a radially outer side of the screw rotor 1 to its inner side, is made smaller, as compared with the variation width resulting when all the tooth portions of the gate rotor 2 overlap with the first plane S1 containing the screw rotor center axis 1a. In addition, the term, “circumferential direction of the gate rotor 2,” can be reworded as the rotational direction of the tooth portion 20 of the gate rotor 2 to be in contact with the side faces 11 of the groove portion 10 of the screw rotor 1. Also, the term, “variation width of the screw rotor 1 from a radially outer side of the screw rotor 1 to its inner side,” refers to a variation width of the inclination angles of all the groove portions 10 from radially outer side to inner side of the screw rotor 1 to be concurrently in contact with the tooth portions 20 of the gate rotor 2.
Therefore, edge angles δ1, δ2 (see
In consequence, in the present invention, it has been found that in the PP-type single screw compressor, the angle of side faces of the groove portions 10 of the screw rotor 1 to be in contact with the tooth portions 20 of the gate rotor 2 is varied by shifting the position of the gate rotor 2 relative to the screw rotor 1.
Also, since the positional-shift distance d is 0.05 to 0.4 time as large as the outer diameter D of the tooth portion 20 of the gate rotor as viewed in the direction orthogonal to the third plane S3, the variation width of the screw rotor groove inclination angle β can be made even smaller.
Also, as viewed in the direction orthogonal to the third plane S3, the gate rotor center axis 2a is inclined by 5° to 30° against the second plane S2 so that a tooth portion 20 of the gate rotor 2 closer to the screw rotor 1 becomes closer to the screw rotor center axis la than a tooth portion 20 of the gate rotor 2 farther from the screw rotor 1. Therefore, the variation width of the screw rotor groove inclination angle β can be made even smaller.
That is, in the PP-type single screw compressor, the velocity of the screw rotor 1 engaged with the gate rotor 2 has large differences between outer peripheral portions and central portion. In particular, at the central portion of the screw rotor 1, the rotational speed of the gate rotor 2 becomes larger relative to the rotational speed of the screw rotor 1, so that the screw rotor groove inclination angle β is varied to a large extent.
As a solution to this, it can be conceived to increase the axis-to-axis distance L between the screw rotor 1 and the gate rotor 2 so that velocity changes of the screw rotor 1 between outer peripheral portions and central portion of the screw rotor 1 becomes small. However, this incurs a problem that the outer diameter of the screw rotor 1 is increased, leading to an increased maximum diameter of the compressor.
Accordingly, by making the gate rotor center axis 2a inclined by 5° to 30° against a plane orthogonal to the screw rotor center axis 1a, the variation width of the screw rotor groove inclination angle β can be made smaller without increasing the outer diameter of the screw rotor 1.
Also, as viewed in the direction orthogonal to the first plane S1, the distance L between the gate rotor center axis 2a and the screw rotor center axis 1a is 0.7 to 1.2 times as large as the outer diameter D of the gate rotor 2. Therefore, the distance L can be made smaller, allowing a downsizing to be achieved.
In other words, since the changing width of the screw rotor groove inclination angle β can be made small, the variation width of the contact angle between the gate rotor 2 and the screw rotor 1 can be suppressed even if the distance L is reduced. Thus, the downsizing can be achieved while the compression efficiency is maintained.
Also, since the seal portions 21a, 21b of the tooth portions 20 of the gate rotor 2 to be in contact with the groove portions 10 of the screw rotor 1 are formed into a curved-surface shape, leaks of the compressed fluid from engagement portions between the tooth portions 20 of the gate rotor 2 and the groove portions 10 of the screw rotor 1 can be reduced, so that the compression efficiency can be improved.
In other words, since the variation width of the screw rotor groove inclination angle β can be made small, the seal portions 21a, 21b of the gate rotor 2 can be formed into a curved-surface shape. More specifically, without increasing the thickness of the gate rotor 2, maximum and minimum values of the inclination angle of the seal portions 21a, 21b can be fulfilled by machining the groove portions 10 of the screw rotor 1 with an end mill and by forming the seal portions 21a, 21b of the tooth portions 20 of the gate rotor 2 into a curved-surface shape with an end mill.
The present invention is not limited to the above-described embodiment. For example, the groove portion 10 may be provided only in one of the end faces of the screw rotor 1. Also, the number of the gate rotors 2 may be freely increased or decreased. Further, the seal portions 21a, 21b of the tooth portions 20 of the gate rotor 2 to be in contact with the groove portions 10 of the screw rotor 1 may also be formed into an acute-angle shape. Besides, the screw rotor 1 and the gate rotor 2 may be rotated in opposite directions.
Number | Date | Country | Kind |
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2006-299227 | Nov 2006 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP2007/070643 | 10/23/2007 | WO | 00 | 4/29/2009 |
Publishing Document | Publishing Date | Country | Kind |
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WO2008/053749 | 5/8/2008 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
3180565 | Zimmern | Apr 1965 | A |
3904331 | Rylewski | Sep 1975 | A |
3905731 | Zimmern | Sep 1975 | A |
4179250 | Patel | Dec 1979 | A |
7153112 | Zarnoch et al. | Dec 2006 | B2 |
Number | Date | Country |
---|---|---|
54-034086 | Oct 1979 | JP |
60-010161 | Mar 1985 | JP |
06101668 | Apr 1994 | JP |
Number | Date | Country | |
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20100003153 A1 | Jan 2010 | US |