DE112018002168T5 - RADIAL COMPRESSOR - Google Patents

Abstract

A radial compressor includes: a compressor impeller 9 (impeller); a main flow passage 10 in which the impeller is disposed, the main flow passage 10 extending in an axis of rotation direction of the impeller; a sub-flow passage 300 including an upstream communication passage 320 connected to the main flow passage 10 and a downstream communication passage 310 connected to the main flow passage 10 on the impeller side with respect to the upstream communication passage 320; N first separating means (ribs 140) fixed to the bypass passage 300 and arranged while being spaced from each other in a rotating direction of the impeller; and M second separation means (fins 220) (where N - 4 ≤ M ≤ N + 4 holds) fixed on the side of the upstream communication passage 320 with respect to the first separation means in the bypass passage 300, the second separation means being arranged while they are are spaced from each other in the direction of rotation.

Description

Technical field

The present disclosure relates to a centrifugal compressor in which a bypass passage communicating with a main flow passage is formed. The present application claims the benefit of priority based on the Japanese patent application No. 2017 - 086557 filed on April 25, 2017, the contents of which are included here.

State of the art

In some radial compressors, a bypass passage is formed that communicates with a main flow passage. A compressor impeller is disposed in a main flow passage. The main flow passage and the subsidiary flow passage are connected to each other at an upstream connection passage and a downstream connection passage. In an area where the flow rate is small, the high pressure air compressed by the compressor impeller flows backward through the downstream communication passage and the bypass passage. The backward flowing air circulates from the upstream communication passage to the main flow passage. In this way, an apparent flow rate increases, and thus the operating range on the low flow rate side expands.

In a radial compressor described in Patent Literature 1, fixed blades and movable blades are provided in a bypass flow passage. The movable blades are arranged on the side which is further away from the impeller than the fixed blades. The bypass flow passage is opened and closed by the movable blades.

Citation List

patent literature

Patent literature 1: Japanese Patent No. 4798491

Summary

Technical task

Meanwhile, there are cases where, instead of the movable blades, first separating means such as the fixed blades mentioned above are arranged, and the second separating means are arranged while being fixed. The plurality of first separation means and the second separation means are spaced apart from each other in the direction of rotation of an impeller. The air that flows from a downstream communication passage into a bypass passage has a swirl velocity component. The vortex velocity component is suppressed by the first separating means and the second separating means, which extends the operating range. However, in a case where the number of the second separating means is not adequate with respect to the number of the first separating means, the pressure loss disadvantageously increases.

An object of the present disclosure is to provide a centrifugal compressor that is capable of reducing pressure loss.

Solution of the task

To solve the above disadvantages, a centrifugal compressor according to an aspect of the present disclosure includes: an impeller; a main flow passage in which the impeller is disposed, the main flow passage extending in an axis of rotation direction of the impeller; a sub-flow passage that includes an upstream communication passage connected to the main flow passage and a downstream communication passage connected to the main flow passage on the impeller side with respect to the upstream communication passage; N first separating means fixed to the bypass passage and arranged while being spaced from each other in a rotating direction of the impeller; and M second separating means (where N - 4 ≤ M ≤ N + 4 holds) fixed on the upstream connection passage side with respect to the first separating means in the bypass passage, the M second separating means being arranged while being spaced from each other in the rotating direction are.

A thickness of the first separating means in the direction of rotation can be less than or equal to five times a thickness of the second separating means in the direction of rotation.

The downstream connection passage can open between the many first separating means.

An inner wall surface of the upstream communication passage on a side spaced from the impeller may be inclined in a direction closer to the impeller when the inner wall surface comes closer to the main flow passage.

The second separating means can extend in a radial direction of the impeller.

Effects of revelation

According to the present disclosure, it is possible to reduce pressure loss.

list of figures

• 1 is a schematic sectional view of a turbocharger.
• 2 Fig. 12 is a selected diagram of a broken line part in 1 ,
• 3 FIG. 12 is a graph for explaining the relationship between the flow rate of a main flow passage and the flow rate of a sub flow passage.
• 4 (a) is a sectional view taken along a line IVa-IVa in 2 , 4 (b) is a sectional view taken along a line IVb-IVb in 2 ,
• 5 is a table that shows exemplary measurement results of the compression efficiency as a function of the number of ribs and the number of fins.
• 6 is a first graph based on the measurement results given in 5 are shown.
• 7 is a second graph based on the measurement results given in 5 are shown.

Description of embodiments

An embodiment of the present disclosure will be described in detail below with reference to the accompanying drawings. Dimensions, materials, other particular numerical values, and the like shown in the embodiments are only examples for ease of understanding, and the present disclosure is not limited thereby unless otherwise stated. Note that, in the present specification and the drawings, components having substantially the same function and structure are denoted by the same reference numerals, and redundant explanations are omitted. Components that are not directly related to the present disclosure are not shown.

1 is a schematic sectional view of a turbocharger C , Descriptions are made assuming the direction of an arrow L who in 1 is shown the left side of the turbocharger C is. Descriptions are made assuming a direction of an arrow R who in 1 is shown the right side of the turbocharger C is. One side of a compressor impeller 9 (Impeller) of the turbocharger C , which will be described below, functions as a radial compressor. Below is the turbocharger C described as an example of a radial compressor. However, the radial compressor is not on the turbocharger C limited. The radial compressor can be in a device other than the turbocharger C may be included, or may be a separate device.

As in 1 shown includes the turbocharger C a turbocharger main body 1 , The turbocharger main body 1 includes a bearing housing 2 , A turbine casing 4 is with the left side of the bearing housing 2 through a fastening bolt 3 connected. A compressor housing 10 is with the right side of the bearing housing 2 through a fastening bolt 5 connected.

A camp hole 2a is in the bearing housing 2 educated. The bearing hole 2a penetrates through the turbocharger C in the left-right direction. A warehouse 6 is in the bearing hole 2a intended. In 1 is a fully floating bearing as an example of the bearing 6 shown. However, the camp can 6 another radial bearing, such as a semi-floating bearing or a rolling bearing. A wave 7 can be swiveled through the bearing 6 held in a freely rotatable manner. At the left end of the shaft 7 is a turbine impeller 8th intended. The turbine impeller 8th is in the turbine housing 4 recorded in a freely rotatable manner. There is also a compressor impeller 9 at the right end of the shaft 7 intended. The compressor impeller 9 is in the compressor housing 100 recorded in a freely rotatable manner.

A case hole 110 is in the compressor housing 100 educated. The case hole 110 opens on the right side of the turbocharger C , A mounting element 200 is in the case hole 110 arranged. A main flow passage 10 is through the compressor housing 100 and the mounting element 200 educated. The main flow passage 10 opens to the right side of the turbocharger C , The main flow passage 10 extends in the direction of the axis of rotation of the compressor impeller 9 (hereinafter simply referred to as the axis of rotation direction). The main flow passage 10 is connected to an air filter (not shown). The compressor impeller 9 is in the main flow passage 10 arranged.

In a state in which the bearing housing 2 and the compressor housing 100 through the fastening bolt 5 are connected is a diffuser flow passage 11 educated. The diffuser flow passage 11 is due to opposite surfaces of the bearing housing 2 and the compressor housing 100 educated. The diffuser flow passage 11 pressurizes the air. The diffuser flow passage 11 is outside from an inside in the radial direction of the shaft 7 annular educated. The diffuser flow passage 11 is with the main flow passage 10 connected on the inside in the radial direction.

In addition, the compressor housing 100 with a compressor scroll flow passage 12 Mistake. The compressor scroll flow passage 12 is ring-shaped. The compressor scroll flow passage 12 is, for example, on an outside of the diffuser flow passage 11 in the radial direction of the shaft 7 arranged. The compressor scroll flow passage 12 is connected to an intake port of an engine (not shown). The compressor scroll flow passage 12 is also with the diffuser flow passage 11 connected. If the compressor impeller 9 turns, the air enters the compressor housing 100 from the main flow passage 10 sucked. The sucked air is used in the process of flow by blades of the compressor impeller 9 accelerated and pressurized. The accelerated and pressurized air passes through the diffuser flow passage 11 and the compressor scroll flow passage 12 pressurized further. The pressurized air is directed to the engine intake port.

An exhaust port 13 is in the turbine housing 4 educated. The discharge opening 13 opens to the left of the turbocharger 10 , The discharge opening 13 is connected to an exhaust gas purification device (not shown). The turbine housing 4 is with a flow passage 14 and a turbine scroll flow passage 15 Mistake. The turbine spiral flow passage 15 is ring-shaped. The turbine spiral flow passage 15 is, for example, on an outside of the flow passage 14 in the radial direction of the turbine impeller 8th arranged. The turbine spiral flow passage 15 is connected to a gas inlet opening (not shown). Exhaust gas discharged from an exhaust manifold of the engine (not shown) is directed to the gas inlet port. The gas inlet port is also with the flow passage described above 14 connected. That from the gas inlet port to the turbine scroll flow passage 15 directed exhaust gas becomes the exhaust port 13 over the flow passage 14 and between blades of the turbine impeller 8th directed. That to the discharge opening 13 guided exhaust turns the turbine impeller 8th in the process of flowing through.

The torque of the turbine impeller 8th is then on the compressor impeller 9 over the wave 7 transfer. As described above, the rotating force of the compressor impeller 9 that air is pressurized and directed to the engine intake port.

2 Fig. 12 is a diagram of a dash line part made up of 1 is selected. As in 2 is shown is a partition 120 in the case hole 110 educated. The partition 120 is ring-shaped. The partition 120 extends in the rotational axis direction. The partition 120 is radially inward from the inner peripheral surface of the housing hole 110 spaced. The inner peripheral surface of the housing hole 110 and the outer peripheral surface of the partition 120 are parallel to the direction of the axis of rotation. However, the inner peripheral surface of the housing hole 110 and the outer peripheral surface of the partition 120 may be inclined with respect to the axis of rotation direction, or may not be parallel to each other.

A head start 130 is on a floor surface 111 of the housing hole 110 educated. The lead 130 is ring-shaped. The lead 130 extends in the rotational axis direction. The lead 130 is radially inward from the inner peripheral surface of the housing hole 110 spaced. The outer peripheral surface of the protrusion 130 is parallel to the direction of the axis of rotation. However, the outer peripheral surface of the protrusion 130 be inclined with respect to the axis of rotation.

The outer peripheral surface of the partition 120 and the outer peripheral surface of the protrusion 130 are flush. It should be noted that the outer diameter of the partition 120 can be larger or smaller than the outer diameter of the projection 130 , An end face 121 the partition 120 on the left (side of the tab 130 ) in 2 and an end face 131 of the lead 130 on the right side (side of the partition 120 ) in 2 are spaced in the axis of rotation direction. A gap (downstream connection passage 310 , which will be described below) is between the end face 121 the partition 120 and the face 131 of the lead 130 educated.

ribs 140 (first release agent) are in the housing hole 110 educated. Many ribs 140 are in the circumferential direction of the partition 120 (Direction of the compressor impeller 9 ) spaced from each other. In 2 is a rib 140 indicated by cross-hatching to facilitate understanding. Ribs 140 are with the floor area 111 of the housing hole 110 molded in one piece. Ribs 140 stand out from the floor area 111 to the right side (slat side, described below) in 2 in front. Ribs 140 are also with the inner peripheral surface of the housing hole 110 and the outer peripheral surface of the partition 120 molded in one piece. That is, the partition 120 is with the compressor housing 100 molded in one piece. The partition 120 is held with a gap from the housing hole 110 is maintained. However, the partition can 120 separately from that compressor housing 100 be formed and on the compressor housing 100 be attached.

A partition hole 122 is in the partition 120 educated. The partition hole 122 penetrates the partition 120 in the axis of rotation direction. In the partition hole 122 are a large diameter section 122a , a section with reduced diameter 122b and a small diameter section 122c educated. The large diameter section 122a opens on an end face 123 the partition 120 on the right side (the one of the ledge 130 opposite side) in 2 , The section with reduced diameter 122b is with the left side (side of the tab 130 ) of the large diameter section 122a in 2 continuous. The inside diameter of the reduced diameter section 122b decreases towards the left side (side of the protrusion 130 ) in 2 , The inside diameter of the small diameter section 122c is smaller than the inside diameter of the large diameter section 122a , The small diameter section 122c is with the left side (side of the tab 130 ) of the section with reduced diameter 122b in 2 continuous. This example has described the case where the large diameter section 122a , the section with reduced diameter 122b as well as the small diameter section 122c are trained. However, their shape doesn't matter as long as the partition hole 122 is trained.

A projection hole 132 is in the compressor housing 100 educated. The projection hole 132 penetrates the lead 130 in the axis of rotation direction. The projection hole 132 is the partition hole 122 across from. Part of the compressor impeller 9 is in the projection hole 132 and the partition hole 122 arranged. The inner peripheral surface of the projection hole 132 agrees with the outer shape of the compressor impeller 9 match. The inside diameter of the projection hole 132 towards the right side (side of the partition hole 122 ) in 2 smaller. The partition hole 122 and the projection hole 132 form part of the main flow passage 10 described above.

In the compressor housing 100 the case hole opens 110 on an end face 100a on the right side (the one of the turbine impeller 8th opposite side) in 2 , As described above, the mounting element is 200 in the case hole 110 arranged. The main body section 210 of the mounting element 200 is ring-shaped, for example. The main body section 210 is not limited to an annular shape, and being, for example, part of the main body portion 210 may be cut away in the circumferential direction.

The main body section 210 is, for example, in the housing hole 110 pressed. The mounting element 200 is in the compressor housing in the manner described above 100 assembled. However, the mounting element 200 on the compressor housing 100 by a fastener such as a bolt. The mounting element 200 can with the compressor housing 100 be connected.

A mounting hole 211 is in the main body section 210 educated. The mounting hole 211 penetrates the main body section 210 in the axis of rotation direction. The mounting hole 210 is with the partition hole 122 continuous in the direction of the axis of rotation. In the mounting hole 210 are a section with a reduced diameter 211 and a parallel section 211b educated. The inside diameter of the reduced diameter section 211 towards the left side (side of the compressor impeller 9 ) in 2 smaller. The parallel section 211b is on the left side (side of the compressor impeller 9 ) in 2 with respect to the reduced diameter section 211 arranged. The parallel section 211b has a substantially constant inner diameter along the axis of rotation direction. The inside diameter of the parallel section 211b of the mounting hole 211 is approximately equal to the inside diameter of the large diameter section 122a the partition hole 122 , This example has described the case where the reduced diameter section 211 and the parallel section 211b are trained. However, their shape doesn't matter as long as the mounting hole 211 is trained.

In the main body section 210 of the mounting element 200 the assembly hole opens 211 on an end face 212 on the right side (that of the compressor impeller 9 opposite side) in 2 , The face 100a of the compressor housing 100 and the face 212 of the mounting element 200 are, for example, flush with each other. However, the face can 100a of the compressor housing 100 on the left side (side of the compressor impeller 9 ) in 2 with respect to the face 212 of the mounting element 200 be arranged. That is, the mounting element 200 can from the case hole 110 to the right side (the side away from the compressor impeller 9 ) in 2 protrude. The face 212 of the mounting element 200 can be on the left side (side of the compressor impeller 9 ) in 2 with respect to the face 100a of the compressor housing 100 be arranged.

In the main body section 210 of the mounting element 200 is the face 213 on the left side (side of the compressor impeller 9 ) in 2 conical. The face 213 is to the left (side of the compressor impeller 9 ) in 2 arranged when it extends radially inward. The face 213 of the mounting element 200 and the face 123 the partition 120 are spaced in the axis of rotation direction. Part of the face 213 the face lies on the inside in the radial direction 123 the partition 120 opposite in the axis of rotation direction. A gap (upstream communication passage 320 , which will be described below) is between the end face 123 the partition 120 and the face 213 of the mounting element 200 educated.

slats 220 (second release agent) are on the face 213 educated. The many slats 220 are from each other in the circumferential direction of the main body portion 210 (the direction of rotation of the compressor impeller 9 ) spaced. In 2 is a slat 220 indicated by a cross hatch that is less dense than that of the rib 140 to facilitate understanding. The slats 220 are for example with the mounting element 200 molded in one piece. However, the slats can 220 separately from the mounting element 200 be formed and on the mounting element 200 be attached. In the bypass passage 300 are the positions of the slats 220 fixed.

A slat 220 has an inner peripheral portion 221 and an outer peripheral portion 222 , The outer peripheral section 222 is radially outside of the inner peripheral portion 221 arranged. The inner peripheral section 221 is continuous with the outer peripheral portion 222 in the radial direction. The inner peripheral section 221 is a section of the slat 220 that of the face 123 the partition 120 opposite. The inner peripheral section 221 extends from the face 213 to the face 123 the partition 120 , An inner circumferential end 221a of the inner peripheral portion 221 is substantially flush with the inner peripheral surface of the parallel portion 211b of the mounting element 200 and the inner peripheral surface of the large diameter portion 122a the partition 120 , However, the inner peripheral end 221a of the inner peripheral portion 221 radially outside of the inner peripheral surface of the parallel portion 211b of the mounting element 200 and the inner peripheral surface of the large diameter portion 122a the partition 120 be arranged. The outer peripheral section 222 extends to the left side (side of the compressor impeller 9 ) in 2 wider than the inner peripheral portion 221 does. The outer peripheral section 222 stands in the gap between the outer peripheral surface of the partition 120 and the inner peripheral surface of the housing hole 110 in front.

The main flow section 10 includes the mounting hole 211 , the partition hole 122 and the projection hole 132 , The bypass passage 300 is on the radial outside of the main flow passage 10 educated. The bypass passage 300 includes the gap between the outer peripheral surface of the protrusion 130 and the outer peripheral surface of the partition 120 and the inner peripheral surface of the housing hole 100 , The bypass passage 300 extends in a ring. The bypass passage 300 includes the downstream communication passage 310 and the upstream communication passage 320 , The downstream connection passage 310 is through the face 121 the partition 120 and the face 131 of the lead 130 educated. The upstream connection passage 320 is through the face 123 the partition 120 , the face 213 of the mounting element 200 and the slats 220 (Inner peripheral sections 221 ), which are adjacent to each other in the circumferential direction. Therefore, there are several upstream communication passages 320 formed while being spaced in the circumferential direction.

The upstream connection passages 320 are with the main flow passage 10 in connection. The downstream connection passage 310 is with the main flow passage 10 on the left side (side of the compressor impeller 9 , the downstream side in the flow direction of the main flow passage 10 ) in 2 with respect to the upstream communication passage 320 in connection.

As described above, the face is 213 of the mounting element 200 conical. That is, in the upstream communication passage 320 is an inner wall surface 321 on the right side (the side facing the compressor impeller 9 is spaced, the side of the end face 100a) in 2 inclined in a direction facing the compressor impeller 9 approaches (towards the face 123 ) if the inner wall surface 321 closer to the main flow passage 10 is (if the inner wall surface 321 extends radially inward). A cross-sectional shape of the inner wall surface 321 , in the 2 shown may be linear or curved. Because the inner wall surface 321 is inclined, the air connects backwards in the upstream communication passage 320 flows along the air flowing in the main flow passage 10 flows. This reduces pressure loss. However, the inner wall surface can 321 extend parallel to the radial direction. The inner wall surface 321 can be in a direction away from the compressor impeller 9 (in a direction away from the face 123 ) be inclined when the inner wall surface 321 closer to the main flow passage 10 is (if the inner wall surface 321 extends radially inwards).

The rib 140 is on the downstream communication passage side 310 in the bypass passage 300 intended. The downstream connection passage 310 opens between the many ribs 140 that are spaced apart in the circumferential direction. A radially outer end of the downstream communication passage 310 opens between the many ribs 140 , For example, in a case where the rib 140 from the floor area 111 to the side of the slats 220 is spaced and the downstream communication passage 310 to the left in 2 regarding the rib 140 opens the air backwards from the downstream communication passage 310 flows, one end of the rib 140 on the side of the floor surface 111 meet what can lead to a division. Because the radially outer end of the downstream communication passage 310 between the many ribs 140 opens, such a division is avoided. However, the downstream communication passage may become 310 on the left in 2 regarding the rib 140 open as long as the effect of a division is limited to a degree that does not involve a disadvantage due to other design conditions.

The downstream connection passage 310 is the compressor impeller 9 across from. A radially inner end of the downstream communication passage 310 opens on an inner peripheral surface of the compressor housing 100 that the compressor impeller 9 opposite in the radial direction.

The downstream connection passage 310 extends, for example, parallel to the radial direction. However, the downstream connection section 310 be inclined with respect to the radial direction. The downstream connection passage 310 can face the right side (upstream communication passage side 320 ) in 2 be inclined when the downstream communication passage 310 extends radially outwards. The downstream connection passage 310 can face the left side (the upstream communication passage 320 opposite side) in 2 be inclined when the downstream communication passage 310 extends radially outwards.

The slat 220 is on the upstream communication passage side 320 in the bypass passage 300 intended. The outer peripheral section 222 the slat 220 is in the bypass passage 300 arranged. The inner peripheral section 221 is in the upstream communication passage 320 arranged.

The bypass passage 300 is in the circumferential direction by the ribs 140 and the slats 220 divided. That is, in the area where the ribs 140 and the slats 220 are arranged, the bypass passage 300 divided into a plurality of flow passages spaced in the circumferential direction.

3 Fig. 10 is a graph for explaining the relationship between the flow rate of the main flow passage 100 and the flow rate of the bypass passage 300 , As in 3 flows in an area where the flow rate of the main flow passage 10 is high, the air in the bypass passage 300 forward (the air flows in the same direction as in the main flow passage 10 , and thus air flows from the upstream communication passage side 320 to the side of the downstream communication passage 310 ). Because the flow rate of the main flow passage 10 is larger, the forward flow rate in the bypass passage increases 300 ,

In the area where the flow rate of the main flow passage 10 is small, the high pressure air flows through the compressor impeller 9 is compressed backwards into the bypass passage 300 (The air flows in a direction opposite to the flow direction of the main flow passage 10 , and thus the air flows from the downstream communication passage side 210 to the upstream communication passage side 320 ). Because the flow rate of the main flow passage 10 is smaller, the flow rate of the reverse flow in the bypass passage 300 greater. The air in the bypass passage 300 flows backward, circulates to the main flow passage 100 from the upstream communication passage 320 out. As a result, the apparent flow rate increases and thus the Operating area on the low flow rate side.

The air flowing backward from the downstream communication passage 310 to the bypass passage 300 flows, swirls under the influence of the rotation of the compressor impeller 9 , The eddy current is in the same direction as the direction of rotation of the compressor impeller 9 , In the case where the bypass passage 300 through the ribs 140 and the slats 220 is divided, the vortex velocity component of the air flowing from the upstream communication passage 320 to the main flow passage 10 circulates, suppresses. The pressure on the inlet side of the compressor impeller 9 increases, and thus the operating range on the low flow rate side continues to expand.

4 (a) is a sectional view along the line IVa-IVa in 2 , 4 (b) is a sectional view taken along a line IVb-IVb in 2 , In 4 (a) are the radially outer section of the compressor housing 100 and the compressor impeller 9 Not shown.

In the in 4 (a) shown example, three ribs are formed. Ribs 140 are equally spaced in the circumferential direction of the partition 120 spaced. However, the ribs must 140 not spaced evenly (the distances may change). In the in 4 (b) The example shown is four slats 220 educated. The slats 220 are equally spaced in the circumferential direction of the partition 120 spaced. However, the slats must 220 not spaced evenly (the distances may change).

The arrangement of the slats 220 in the circumferential direction with respect to the arrangement of the ribs 140 in the circumferential direction is not limited to the positional relationship shown in FIGS 4 (a) and 4 (b) is shown. At least one of the slats 220 can a rib 140 face each other in the rotational axis direction. It is not necessary for one of the slats 220 a rib 140 is opposite in the rotational axis direction.

The thickness La of the ribs 140 in the direction of rotation is less than or equal to five times the thickness lb of the slats 220 in the direction of rotation. In a case where the thickness La the ribs 140 in the direction of rotation five times the thickness lb of the slats 220 in the direction of rotation, there will be a gap between adjacent ribs 140 closely. The flow rate of air through the gap between adjacent fins 140 flows, increases. The effect of a separation on the slats 220 , which will be described below, increases.

In this case there is a separation on the wall surfaces of the slats 220 on the side of the direction of rotation because the flow velocity of the air increases. More specifically, the separation current does not adhere to the wall surfaces of the slats 220 and dividing bubbles spread in the direction of the rotation axis. As the division bubbles spread in the axis of rotation direction, the loss increases due to the increasing degree of separation. On the other hand, in a case where the thickness La the ribs 140 in the direction of rotation less than or equal to five times the thickness lb of the slats 220 is in the direction of rotation, the effect of separation is suppressed and the compression efficiency improves. However, the thickness La the ribs 140 in the direction of rotation five times the thickness lb of the slats 220 in the direction of rotation as long as the effect of a separation is limited to a degree that does not involve a disadvantage due to other design conditions.

The slats 220 extend parallel to each other in the radial direction of the compressor impeller 9 (radially along the radial direction). However, the slats can 220 with respect to the radial direction of the compressor impeller 9 be inclined. For example, the outer peripheral end of the lamella 220 in the direction of rotation with respect to the inner peripheral end of the lamella 220 be offset. Ribs 140 extend parallel to each other in the radial direction of the compressor impeller 9 (radially along the radial direction). However, the ribs can 140 with respect to the radial direction of the compressor impeller 9 be inclined. For example, the outer peripheral end of a rib 140 in the radial direction with respect to the inner peripheral end of the rib 140 be offset.

5 is a table that shows exemplary measurement results of the compression efficiency as a function of the number of ribs 140 and the number of slats 220 shows. 6 is a first graph based on the in 5 shown measurement results. In the 5 and 6 the rate of increase / decrease (%) of the compression efficiency is displayed using the case where the number of ribs 140 (the number of ribs) is three and the number of fins 220 (the number of slats) as a reference value is eight.

As in 6 is shown in the case of the three ribs 140 the compression efficiency is greater than the reference value when the fins 220 in a first area X are (seven or fewer slats 220 ). In the case of the six ribs 140 the compression efficiency is higher than the reference value when the fins 220 in a first area Y are (two to ten slats 22 ). In the case of nine ribs 140 the compression efficiency is higher than the reference value when the fins 220 in a first area Z are (five to thirteen slats 220 ).

Based on the 5 and 6 becomes a reasonable range of the number of slats 220 regarding the number of ribs 140 obtained. That is, it is believed that N ribs 140 are arranged and M slats 220 are arranged, whereby N and M are natural numbers. In this example, the ribs are 140 and the slats 220 arranged so that N - 4 ≤ M ≤ N + 4 is satisfied.

As described above, in the case where the bypass passage 300 through the ribs 140 and the slats 220 is divided, the swirl speed component of the air flowing from the upstream communication passage 320 to the main flow passage 10 circulates, suppresses. The pressure on the inlet side of the compressor impeller 9 increases, and thus the operating range on the low flow rate side expands. However, in a case where the number of slats increases 220 regarding the number of ribs 140 is too large, the pressure loss due to the effect of a division at one end 223 (please refer 2 ) of a slat 220 on the side of the rib 140 occurs. By doing M slats 220 For N ribs 140 (where N - 4 M M N N + 4 holds), the pressure loss is suppressed while the vortex velocity component of the air is suppressed, which improves the compression efficiency.

7 is a second graph based on the in 5 shown measurement results. In 7 are the ranges of the number of slats 220 (first areas X ' . Y ' and Z ' ) tighter than those in 6 ,

As in 7 is shown in the case of the three ribs 140 the compression efficiency is particularly high when fins 220 in a first area X ' are (one to five slats 220 ). In the case of six ribs 140 the compression efficiency is particularly high when the slats 220 in a second area Y ' are (four to eight slats 220 ). In the case of nine ribs 140 , the compression efficiency is particularly high when the lamellas 220 in a second area Z ' are (seven to eleven slats 220 ).

That is, by M slats 220 For N ribs 140 (where N - 2 M M N N + 2 holds) are arranged, the pressure loss is further suppressed while the vortex velocity component of the air is suppressed, which further improves the compression efficiency. Here it is preferable to reduce the difference in the number of objects between the N ribs 140 and the M slats 220 are to be arranged. In this case, the change in the flow passage area of the air (fluid) through the fins 140 and the slats 220 occurs, reduced. As a result, this can suppress the loss caused by the acceleration or deceleration of the air in the bypass passage 300 is effected. For example, when the air is accelerated, the effect of the above division becomes large. The loss due to the effect of the division can be expected to be suppressed. In addition, when the air is decelerated, for example, the ratio of the speed component in the circumferential direction increases. As a result, a mixed loss is predicted to increase due to a combination of the main stream and the stream entering the main stream from the upstream communication passage 320 flows. This mixing loss can be expected to be suppressed.

Although an embodiment of the present disclosure has been described with reference to the accompanying drawings, it is to be understood that the present disclosure is not limited to the above embodiment. It is to be understood that those skilled in the art can contemplate various modifications or variations within the scope described in the claims, and it is to be understood that these are of course also within the technical scope of the present disclosure.

Industrial applicability

The present disclosure can be effectively applied to a radial compressor in which a bypass passage connected to a main flow passage is formed.

LIST OF REFERENCE NUMBERS

9

Compressor impeller (impeller)

10

Main flow passage

140

Rib (first release agent)

220

Lamella (second release agent)

300

Besides flow passage

310

Downstream connection passage

320

Upstream connection passage

321

Inner wall surface

C

Turbocharger

QUOTES INCLUDE IN THE DESCRIPTION

This list of documents listed by the applicant has been generated automatically and is only included for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Patent literature cited

• JP 2017 [0001]
• JP 086557 [0001]
• JP 4798491 [0004]

Claims (5)

Radial compressor, with: an impeller; a main flow passage in which the impeller is disposed, the main flow passage extending in an axis of rotation direction of the impeller; a secondary flow passage that includes an upstream communication passage connected to the main flow passage and a downstream communication passage connected to the main flow passage on the impeller side with respect to the upstream communication passage; N first separating means fixed to the bypass passage and arranged while being spaced from each other in a rotating direction of the impeller; and M second separating means (where N - 4 ≤ M ≤ N + 4 holds) fixed on the upstream communication passage side with respect to the first separating means in the bypass passage, the M second separating means being arranged while being spaced from each other in the rotation direction , Radial compressor after Claim 1 , wherein a thickness of the first release means in the direction of rotation is less than or equal to five times a thickness of the second release means in the direction of rotation. Radial compressor after Claim 1 or 2 , wherein the downstream connection passage between the many first separating means opens. Radial compressor according to one of the Claims 1 to 3 , wherein an inner wall surface of the upstream communication passage on a side spaced from the impeller is inclined in a direction closer to the impeller when the inner wall surface comes closer to the main flow passage. Radial compressor according to one of the Claims 1 to 4 , wherein the second separating means extend in a radial direction of the impeller.

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