JP3752210B2 - Centrifugal compressor, diffuser blade, and manufacturing method thereof - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a centrifugal compressor, a diffuser blade, and a manufacturing method thereof.
[0002]
[Prior art]
A centrifugal compressor is known as a compressor that compresses gas. As shown in FIG. 10, the centrifugal compressor includes a rotating shaft 101 to which an impeller 103 is attached and a casing 102. A rotor blade 104 is attached to the impeller 103, and a ring-shaped disk 106 and a casing main body 107 are configured in the casing 102 as a swirl flow forming opposing wall that forms a passage for guiding a swirl flow 105 having a centrifugal component in the radial direction. Has been. A plurality of diffuser blades 108 are fixed between the opposed surfaces of the annular disk 106 and the casing body 107 and are arranged in the same circumference at the same angular intervals. The casing on the side where the annular disk 106 is attached is called a shroud casing. The diffuser blade 108 is joined to the annular disk 106 by welding, or the diffuser blade 108 and the annular disk are integrally formed by machining.
[0003]
A plurality of rotor blades 104 rotating in the same body as the rotating shaft 101 gives work to the gas in the annular space between the impeller 103 and the casing 102. In the vicinity of the outlet end portion of the rotor blade 104, the centrifugal component flow 105 increases in pressure, and the circumferential component increases to form a swirling flow that swirls at high speed in the rotation direction of the impeller 103. A gas swirl flow 105 discharged from the rotor blade 104 with a centrifugal direction component and a circumferential direction component has a swirl direction flow velocity component 109 and a radial flow velocity component 110, as shown in FIG. The flow angle α is defined as an angle between the swirling flow 105 and the swirling direction flow velocity component 109. The swirling flow 105 is converted into a high-pressure flow 111 that receives a force from the diffuser blade 108 and decelerates to increase the pressure. A centrifugal compressor compresses gas by such high pressure.
[0004]
A known typical diffuser blade 108 shown in FIG. 10 is formed as a columnar body whose sectional shape is the same in the axial direction 113, which is cut at an arbitrary axial position parallel to the reference plane 112 of the annular disk 106. Yes. As shown in FIGS. 12A, 12B, and 12C, the diffuser blade 108 defined on the two-dimensional plane in this way has the left and right end surfaces 116 and 117 shaved by the NC with the cylindrical blade 114. It is put out and shaped. When the end face 118 of the cylindrical blade 114 has a turning ability, the reference surface 112 that is a ring-shaped disk surface can be formed simultaneously with the formation of the surface shapes of the two blade surfaces 116, 117, and the ring-shaped A diffuser blade 108 integrated with the disk 106 can be produced. The wing surfaces 116 and 117 are formed by controlling the movement trajectory of the rotational axis of the cylindrical blade 114 by the NC. Thereby, as described in FIGS. 12A, 12B, and 12C, the above-described two-dimensional surface shape can be given to the diffuser blade 108. The diffuser thus manufactured and having a two-dimensional surface shape in a columnar shape is named a two-dimensional diffuser.
[0005]
13 (a) and 13 (b) show a comparison of the shape of the impeller outlet portion of the compressor for high flow rate and the compressor for low flow rate. The large flow rate and the small flow rate are compared based on the ratio (= b / D) between the outlet side width b of the rotor blade 104 and the impeller diameter D. Due to the relative magnitude of this ratio, the large flow rate type and the small flow rate type are relatively compared. Among the two compressors of FIGS. 13 (a) and (b), the compressor of FIG. 13 (a) is said to be relatively large flow type with respect to the compressor of FIG. 13 (b), The compressor of FIG. 13 (b) is said to be a relatively small flow type relative to the compressor of FIG. 13 (a). Many compressors are distributed around 0.05 to 0.1 as the center of the ratio.
[0006]
14 (a) and 14 (b) show the spatial distribution of the flow angle α of the compressor of FIG. 13 (a) and the flow angle α of the compressor of FIG. 13 (b). The horizontal axes in FIGS. 14A and 14B respectively indicate the axial distances of the diffuser blades 108 (the height position in the axial direction 113 shown in FIG. 11), and the horizontal axes in FIGS. Each vertical axis represents the flow angle α of the diffuser blade 108. Position A indicates a ring-shaped disk side position (low position of the diffuser blade 108), and position B indicates a position opposite to the position A (high position of the diffuser blade 108). The flow angle distribution has a parabola distribution region K in which a boundary layer develops at the wall surface positions corresponding to the positions A and B, and is distributed in a parabolic shape in a height region close to the positions A and B. The flow angle distribution of the large flow type compressor is a linear distribution that is linearly distributed in a middle region between the boundary layer end C on the position A side and the boundary layer end D on the position B side. There may be a region J. In the small flow type compressor, the edge C of the boundary layer on the position A side and the edge D of the boundary layer on the position B side coincide with each other, and there is no linear distribution region of the flow angle α.
[0007]
In a known compressor, the blade angle (the angle between the center line of the diffuser blade 108 and the circumferential line) is constant as shown by a one-dot chain line in the figure. Incidence In is defined as the difference between the blade angle and the flow angle α. Incidence is shown with diagonal lines in the figure. Incidence In increases in the vicinity of the wall surface of position A, in the vicinity of the wall surface of position B, and in the central height region between position A and position B. In common. In a compressor having a higher incidence In, the loss due to the blade angle shape is larger, and the diffuser performance is further deteriorated.
[0008]
The improvement in the incidence can be expressed as a function of an arbitrary position between the position A and the position B (distance from the reference plane 112 of the annular disk 106) H. If the blade angle is expressed by αLE, the incidence (αLE−α) is generally expressed by (αLE (H) −α (H). If the integration of the incidence shown in FIG. The blade shape-induced loss corresponding to the integral based on the function shape of the blade angle and the function shape of the flow angle becomes smaller, and improvement of the blade shape based on such a viewpoint is known from Japanese Patent Laid-Open No. 10-77997. Such a known improvement technique makes the blade angle (particularly the blade entrance angle or blade leading edge angle) α (H) out of the flow angle and blade angle by curving the leading edge shape line of the blade. It is a curve.
[0009]
Although it is certain that the loss is strongly influenced by the integral value of the incident as suggested in the above-mentioned known literature, consideration regarding the distribution in the blade height direction of the incident is required for performance improvement.
[0010]
It is required to establish a technique that more effectively suppresses the deterioration of the diffuser performance by taking into account the distribution of the incidence in the blade height direction. Further, it is required to correct the blade shape based on the structure of the centrifugal flow having the distribution of the incidence blade height direction, and in particular, it is required to establish a method for forming the required diffuser shape.
[0011]
[Problems to be solved by the invention]
An object of the present invention is to provide a centrifugal compressor, a diffuser blade, and a manufacturing method thereof that can more effectively suppress a decrease in the diffuser performance by considering the distribution of the incidence in the blade height direction. is there.
Another object of the present invention is to correct the diffuser blade shape based on the distribution of the incidence blade height direction, thereby further effectively suppressing a decrease in diffuser performance, It is to provide a diffuser blade and a manufacturing method thereof.
Still another object of the present invention is to provide a method of manufacturing a diffuser blade capable of establishing a technique for generating such a diffuser shape.
[0012]
[Means for Solving the Problems]
Means for solving the problem is expressed as follows. Technical matters appearing in the expression are appended with numbers, symbols, etc. in parentheses (). The numbers, symbols, and the like are technical matters constituting at least one embodiment or a plurality of embodiments of the present invention or a plurality of embodiments, in particular, the embodiments or examples. This corresponds to the reference numbers, reference symbols, and the like attached to the technical matters expressed in the drawings corresponding to. Such reference numbers and reference symbols clarify the correspondence and bridging between the technical matters described in the claims and the technical matters of the embodiments or examples. Such correspondence and bridging does not mean that the technical matters described in the claims are interpreted as being limited to the technical matters of the embodiments or examples.
[0013]
A diffuser blade of a centrifugal compressor according to the present invention is shown in FIG. The plurality of diffuser blades (1) are fixedly arranged around the rotation region of the rotary blade (104) similar to FIG. The diffuser blade (1) forms a leading edge portion (3) on the upstream side. The leading edge portion (3) is formed on a leading edge shape line (4) formed in a convex shape toward the downstream side. The leading edge shape line (4) is expressed as a function of the height position defined in the axial direction of the rotor blade (104), and is a parabolic shape formed in a convex shape toward the downstream side. There is at least one vertex, and it is not denied that the vertex is multipointed.
[0014]
The leading edge shape line (4) has two regions of shape lines that are divided in the height direction defined in the axial direction of the rotor blade (104). The leading edge shape line (4) is composed of a lower leading edge shape line (11) in a region lower in the height direction and a higher leading edge shape line (12) in a region higher in the height direction. Has been. It is important for improving the compression efficiency that the lower leading edge shape line (11) and the higher leading edge shape line (12) are asymmetric in the height direction corresponding to the asymmetry of the swirling flow (105). It is.
[0015]
The height direction width of the lower side leading edge shape line (11) is asymmetric as described above in that it is larger than the height direction width of the higher side leading edge shape line. The length in the streamline direction of the lower side leading edge shape line (11) is asymmetric in that it is longer than the length in the streamline direction of the higher side leading edge shape line (12).
[0016]
The side surface facing the rotational direction of the diffuser blade (1) is an arc or a set of arc-shaped curves. The two side surfaces facing the rotational direction and the direction opposite to the rotational direction of the diffuser blade (1) have a side surface shape in the low direction and the high direction in the cross section perpendicular to the flow direction, with the height divided in two. By comprising an arc or an arcuate curve, it has a cross-sectional shape in which the blade thickness of the lowest part and the highest part becomes thicker than the two divided parts. The fact that the shape surface is formed by an arc is the same as a known manufacturing method in that the shape surface is easily manufactured.
[0017]
The diffuser blade according to the present invention has a leading edge shape line formed in a convex shape toward the downstream side. The leading edge shape line formed in a convex shape has a parabolic shape as described above. The leading edge shape line formed in a convex shape may be symmetric or asymmetric.
[0018]
Although the blade angle of the two-dimensional blade is constant and the adjustment of the incidence is impossible, the blade angle αLE (H) and the flow angle α (H) distributed in the curved shape of the centrifugal compressor according to the present invention minimize the incidence. It is possible to adjust in the direction to change. As described above, the function α (H) is preferably parabolic.
[0019]
The fact that a straight line or other curve is interposed between the lower leading edge shape line (11) and the higher leading edge shape line (12) can increase the overall incidence in response to the change in the flow rate. To) ease the adjustment to reduce.
[0020]
The wing (1) is fixed to an annular disk (2) that forms a flow path. The annular disk (2) has a disk surface (6), and the disk surface (6) is a reference surface whose height H is set to zero. The diffuser blade (1) is interposed between the casing (107) and the annular disk (2), and the diffuser blade (1) is fixed to the annular disk (2) integrally or separately.
[0021]
The method for manufacturing a diffuser blade according to the present invention is the above-described method for manufacturing a diffuser blade. A first step of moving the ball end mill 26 with respect to the workpiece base material by numerical control on the first locus, and a second step of moving the ball end mill (26) with respect to the workpiece base material by numerical control on the second locus. It consists of and. The first trajectory and the second trajectory approach each other to form a leading edge shape line.
[0022]
A known manufacturing method for bringing the first trajectory and the second trajectory closer is suitably used to form a parabola of the diffuser blade having the shape line described above. The first step and the second step described above include a step of forming a first diffuser blade portion having a lower front edge shape line (11) and a second diffuser blade having a higher front edge shape line (12). Forming a portion. Forming the low-order front edge shape line (11) and the high-order front edge shape line (12) on the common base material all at once (simultaneously) and facilitating the manufacturing method thereof Is the purpose.
[0023]
DETAILED DESCRIPTION OF THE INVENTION
As in the conventional example of FIG. 10, in the embodiment of the centrifugal compressor according to the present invention, the three-dimensional diffuser blade 1 is joined to the annular disk in FIG. The three-dimensional diffuser blade 1 is joined to the annular disk 2 integrally or by welding. The shape of the leading edge of the blade leading edge portion 3 of the three-dimensional diffuser blade 1 is formed by a partial curve of a parabola or an ellipse. When the leading edge line shape is formed by a cutting locus by the arcuate tip of the ball end mill, two cuttings are performed: a surface opposite to the impeller rotation direction (pressure surface 41) and a rotation direction surface (negative pressure surface 42). It is defined as the intersection of two curved surfaces at the locus.
[0024]
The blade leading edge portion 3 is a portion on the inner peripheral side of the three-dimensional diffuser blade 1. The leading edge line shape 4 of the blade leading edge portion 3 of the annular disk 2 is formed by a parabola in this embodiment. In the present specification, a position closer to the disk surface 6 of the annular disk 2 in the axial direction (height direction) a is referred to as a low position. A position farther from the disk surface 6 in the axial direction a will be referred to as a high position. H of the disk surface 6 of the annular disk 2 is zero.
[0025]
The leading edge shape line 4 extends vertically with respect to the height direction defined in the rotation axis direction of the impeller, with the convex vertex 15 of the leading edge shape line 4 formed convex toward the downstream side as a boundary. Each of the two regions to be divided has a leading edge parabola 12 at the upper part and a leading edge parabola 11 at the lower part. It is composed of a lower part 8 that is a low-order area and an upper part 9 that is a high-order area, with a central plane 7 including the vertex 15 as a boundary. The position coordinate in the height direction of the center plane 7 is not limited to ½ of the blade height H. Each of the lower portion 8 and the upper portion 9 includes a front edge shape surface 13 of a lower portion below the center surface 7 and a front edge shape surface 14 of an upper portion above the center surface 7.
[0026]
The parabola characteristic of the leading edge shape line 4 is the distance that the leading edge parabola 11 in the lower part travels upstream from the vertex 15 when the leading edge parabola 11 in the lower part is projected at right angles to the disk surface 6. As a function of H (distance from the reference plane 112 of the annular disk 106). For the leading edge parabola 12 of the upper part, the distance H (the distance from the reference plane 112 of the ring-shaped disk 106) that travels upstream from the vertex 15 when the leading edge parabola 12 of the upper part is projected at right angles to the disk surface 6. It can be defined as a function of distance). The distance 19 to the end point 16 of the leading edge parabola 11 in the lower part is preferably longer than the distance 21 to the end point 18 of the leading edge parabola 12 in the upper part. The leading edge parabola 4 is not limited to the parabola mathematically defined as described above, and may be a part of an ellipse or a higher-order function, and may have a shape similar to these. Also good.
[0027]
FIG. 2 shows a blade cross-sectional shape cut along a cross section I perpendicular to the flow direction. The two side surfaces of the impeller in the rotational direction and the reverse direction of the rotation are referred to as a pressure surface 31 and a negative pressure surface 32, respectively. The blade cross-sectional shape is configured by a circular arc or a circular arc-shaped side surface in the lower direction and the higher direction with the central plane 7 in the height direction as a boundary. Further, the blade thickness of the lowest part and the highest part has a cross-sectional shape that is thicker than the blade thickness of the central surface 7.
[0028]
As shown in FIG. 10, the swirl flow 105 that is initially generated by the rotor blades 104 is different in speed and direction at the axial position (corresponding to the height direction position) of the rotor blades 104. It is not completely symmetric with respect to direction, but asymmetric. The length 19 and the length 21 are asymmetrical corresponding to the asymmetry of the flow angle of the swirl flow.
[0029]
The blade angle αLE of the blade leading edge is defined in FIG. The blade angle αLE of the blade leading edge passes through the tip point 23 on the surface 22 cut by a plane parallel to the disk surface 6 at an arbitrary height position. It is shown as an angle between a tangent line at the point 23 and an extension line 25 obtained by extending a center line of the cross section 22 (a line connecting the centers of the pressure surface and the suction surface) to the upstream side. On the other hand, the flow angle α has a swirl direction flow velocity component 109 and a radial flow velocity component 110 as shown in FIG. The flow angle α is defined as an angle between the swirling flow 105 and the swirling direction flow velocity component 109.
[0030]
The blade leading edge flow angle α is defined by the angle formed by the swirl direction flow velocity component 109 and the radial flow velocity component 110 on the leading edge shape line 4, and the angle distribution α of the blade leading edge flow angle α with respect to the blade height H. (H) is shown in FIGS. 3 (a) and 4 (a).
[0031]
FIG. 3A shows the blade leading edge flow angle α (H) and blade leading edge blade angle αLE (H) of the large flow type compressor, and FIG. 4A shows the blade leading edge flow angle αLE (H) of the small flow type compressor. An edge flow angle α (H) and a blade leading edge blade angle αLE (H) are shown. 3B and 4B show the direction of the leading edge shape line 4 and the height H. FIG. 3A and 4A, α15 indicates the flow angle of the apex 15 of the leading edge shape line 4, α16 indicates the flow angle of the leading edge shape line 4 at the terminal point 16, and α18 indicates the terminal point. The flow angle at 18 is shown.
[0032]
The blade leading edge flow angle α (H) is indicated by a solid line in FIGS. 3 (a) and 4 (a). In the large flow rate type compressor of FIG. On the other hand, the blade angle αLE of the blade leading edge is set to a parabolic distribution α16-α15-α18 corresponding to the flat blade leading edge shape. The leading edge region blade angle distribution αLE (H) according to the present invention is closer to the flow angle distribution α than the known blade angle distribution (constant distribution) shown in FIGS. 13 (a) and 14 (a). Yes. Therefore, the incident distribution (shaded portion) according to the present invention is generally smaller in the entire height region than the known incident distribution. The same applies to the small flow type compressor of FIG. 4, which is smaller in the overall height region than the known incident distribution.
[0033]
5 and 6 show an embodiment relating to a method of manufacturing a centrifugal compressor according to the present invention. 6 (a), (b), (c), (d), (e) are orthogonal to the center line 25 at the cross-sectional positions X, I, II, III, IV shown in FIG. The cross sections of the three-dimensional diffuser blade 1 cut along planes orthogonal to the disk surface 6 are shown. A tool used to cut the processing base material including the annular disk 2 and integrally manufacture the annular disk 2 and the three-dimensional diffuser blade 1 is a ball end mill 26.
[0034]
The ball end mill 26 has a spherical blade surface 27 having a radius r1 and a cylindrical blade surface 28 having a diameter of 2 × r1 (= d1). The angle β between the center line of the ball end mill 26 and the disk surface 6 of the annular disk 2 can be set freely. The distance between the center plane 29 including the center line of the three-dimensional diffuser blade 1 (corresponding to the center line 25 described above) and the center point of the spherical blade surface 27 is represented by yx, and the axial end surface of the three-dimensional diffuser blade 1 The distance between the 17 edge 31 and the center plane 29 is represented by Zx. The locus of the center point O of the spherical blade surface 27 is set in the NC device (not shown).
[0035]
FIG. 6B shows cross-sectional shape lines 32 on both side surfaces of the three-dimensional diffuser blade 1 at the cross-sectional position I in FIG. In the cross-sectional position, yx> r1. Yx of the cross-sectional position I is represented by yI in the drawing. The cross-sectional shape line 32 at the cross-sectional position I is a composite curve of an arc formed by the spherical blade surface 27 and a straight line formed by the cylindrical blade surface 28.
[0036]
FIG. 6A shows the cross-sectional shape lines of the front edge shape surface 13 in the lower part and the front edge shape surface 14 in the upper part of the three-dimensional front edge shape surface 5 at the cross-sectional position X. Since the cross-sectional position X is a position upstream from the apex 15, the front edge cross-sectional shape line 33 of the lower part of the front edge shape surface 13 of the lower part and the front edge of the upper part of the front edge shape surface 14 of the upper part The cross-sectional shape line 34 is separated by its cross section, and yx <r1 and zx> 0. At the cross-sectional position X, the front edge cross-sectional shape line 33 in the lower part and the front edge cross-sectional shape line 34 in the upper part are both arcs. At the cross-sectional position corresponding to the position of the ball end mill 26 where the ball end mill 26 has advanced by a distance 21 (see FIG. 1) from the position corresponding to the cross-sectional position X, Zx = 0, and the end point 18 appears.
[0037]
At the cross-sectional position corresponding to the position of the ball end mill 26 where the ball end mill 26 has advanced by a distance 19 (see FIG. 1) from the position corresponding to the cross-sectional position X, virtually xx <0, and yx = 0, and the end point 16 appears. yx is a function of the advance length S of the ball end mill 26, and is expressed by yx = yx (S). By defining the function yx, the leading edge shape 11 of the lower part is also applied to the leading edge shape of the upper part. The parabola described above is also given to the line 12.
[0038]
FIG. 6C shows a shape line at the cross-sectional position II. The cross-sectional shape at this position is the same as the cross-sectional shape of FIG. 6B in that it is formed by an arc and a straight line, but the three-dimensional diffuser blade 1 is formed thicker, and the angle βII described above is It is getting bigger. The cross-sectional shape of the cross-sectional position III shown in FIG. 6D is the same as the cross-sectional shapes of FIGS. 6B and 6C in that it is a combination of a circular arc and a straight line, but the angle βIII at this position is Even larger, 90 degrees. The cross-sectional shape of the cross-sectional position IV on the downstream side shown in FIG. 6 (e) is formed by another end mill, and there is substantially no arc, but the disk surface 6 is formed in the same manner as in the known turning. The annular disk 2 can be manufactured simultaneously.
[0039]
FIG. 7 shows the motion locus of the center point O of the ball end mill 26. Both side surfaces of the three-dimensional diffuser blade 1 are defined in a one-to-one correspondence with the movement trajectories of the ball end mills 26 on both sides. Α15 of the blade leading edge flow angle α (H) when the apex 15 appears (formed) is rewritten in FIG. The center point position of the ball end mill 26 when the blade leading edge flow angle α (H) is α15 is indicated by reference numeral 35. The locus of the center point O of the ball end mill 26 is shown on the surface of the disk surface 6 by orthogonal projection with respect to the disk surface 6. The center projection points of the ball end mills 26 on both sides move linearly on the surface of the disk surface 6 from the center point position 35 to the end point 16.
[0040]
In this case, the projection line of the blade leading edge line 4 onto the disk surface 6 is a straight line. Since a linear relationship is given as yx = k × S, the leading edge shape line 11 in the lower part has an elliptical shape. α15 is an angle at the intersection of the projection point of the blade leading edge line 11 on the disk surface 6 and a circle passing through the point 15 (the circle defined above). α16 is an angle at the intersection 16 between the straight line 11 and a circle passing through the point 16. As is known geometrically, if the position going from the vertex 15 toward the terminal point 16 is closer to the vertex 15 (the central angle θ defined by the vertex 15 and the point above the lower part 11 of the leading edge parabola is Α (H) becomes smaller and its function α (H) becomes a parabolic shape as a curve having one vertex, as shown in FIGS. 3 (a) and 4 (a). become.
[0041]
8 (a) and 8 (b) show another embodiment of the centrifugal compressor according to the present invention. Two ball end mills 26 are used on one side of the three-dimensional diffuser blade 1. The two ball end mills 26 move at two different constant heights. In the large flow compressor, as shown in FIG. 14, the thickness of the boundary layer (corresponding to the parabola distribution region K) may be half or less of the blade height H. In such a case, the radius d1 of the ball end mill 26 can be appropriately selected (smaller), and the incidence can be reduced.
[0042]
9 (a) and 9 (b) show still another embodiment of the centrifugal compressor according to the present invention. Although the two ball end mills 26 are used on one side of the three-dimensional diffuser blade 1, it is the same as the embodiment of FIG. This embodiment is different from the embodiment shown in FIG. 8 in that it is variable continuously or discontinuously. Corresponding to the flow rate of the compressor, the height positions and the radii of the two ball end mills 26 can be appropriately changed. In the present embodiment, a straight portion 34 is interposed between the front edge shape line 11 in the lower part and the front edge shape line 12 in the upper part.
[0043]
【The invention's effect】
The centrifugal compressor, the diffuser blade, and the manufacturing method thereof according to the present invention can improve the compression efficiency by adjusting the incidence angle.
[Brief description of the drawings]
FIG. 1 is an oblique axis projection view showing an embodiment of a centrifugal compressor according to the present invention.
2 is a side sectional view of FIG. 1. FIG.
FIGS. 3A and 3B are a cross-sectional view and a graph showing the relationship between the shape of the diffuser blade and the incidence, respectively.
4A and 4B are a cross-sectional view and a graph showing the relationship between the shape of another diffuser blade and the incidence, respectively. FIG.
FIG. 5 is an oblique axis projection view showing a cross-sectional position of a diffuser blade.
6 (a), (b), (c), (d), and (e) are cross-sectional views showing diffuser blades at respective positions.
FIG. 7 is a plan sectional view showing a trajectory of a ball end mill.
FIGS. 8A and 8B are an oblique projection and a side sectional view showing another embodiment of the centrifugal compressor according to the present invention.
FIGS. 9A and 9B are an oblique projection and a side sectional view showing still another embodiment of the centrifugal compressor according to the present invention.
FIG. 10 is a cross-sectional view showing a known compressor.
FIG. 11 is an oblique projection showing a known diffuser blade.
FIGS. 12A, 12B, and 12C are cross-sectional views respectively showing a known diffuser blade manufacturing method.
FIGS. 13A and 13B are a cross-sectional view and a graph showing the relationship between the shape of a known diffuser blade and the incidence, respectively.
14A and 14B are a cross-sectional view and a graph showing the relationship between the shape of another known diffuser blade and the incidence, respectively.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Diffuser blade | wing 2 ... Ring-shaped disk 3 ... Front edge part 4 ... Front end line 5 ... Both-sides side 6 ... Disk surface 11 ... Lower side part 12 ... Upper side part 34 ... Straight line 107 ... Casing

Claims (4)

A manufacturing method of a diffuser blade including a front edge on the front side which is the upstream side and a rear edge on the rear side which is the downstream side,
A first step of moving the ball end mill with respect to the workpiece base material by numerical control on a first locus, and cutting the pressure surface of the diffuser blade;
Moving the ball end mill with respect to the workpiece base material on a second locus by numerical control, and a second step of cutting the suction surface of the diffuser blade,
The intermediate portion in the height direction of the diffuser blade at the front edge is retreated to the rear side with respect to both ends of the height direction at the front edge,
The first trajectory and the second trajectory are close to each other to form the leading edge along a front-rear direction defined by the front side and the rear side;
The diffuser blade is fixed to a reference surface cut out from the workpiece base material,
The height direction is a height direction from the reference plane,
The angle between the rotation axis of the ball end mill and the center plane of the diffuser blade formed by connecting a line perpendicular to the reference plane from the leading edge to the trailing edge is one of the first steps . The part and the part of the second step are inclined at an angle larger than 0 ° and smaller than 90 ° in mutually opposite directions. Each of the first trajectory and the second trajectory includes a high-order trajectory and a low-order trajectory,
Assuming that the coordinate in the height direction in the high-order locus is a high-order coordinate and the coordinate in the height direction in the low-order locus is a low-order coordinate, the high-order coordinates and the low-order coordinates are the respective loci. The method of manufacturing a diffuser blade according to claim 1, which is different from each other. The method of manufacturing a diffuser blade according to claim 2, wherein a difference between the high-order side coordinates and the low-order side coordinates is variable on each of the trajectories. Moving the first ball end mill on the high-order locus,
The method for manufacturing a diffuser blade according to claim 2 or 3, wherein the second ball end mill is moved on the lower locus.

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