DE112012003648T5 - Radial gas expander - Google Patents

Abstract

This radial gas expander 1 is provided with a rotary shaft 3, a vane 4 fixed to the rotary shaft 3, and a housing 2 through which the rotary shaft 3 is rotatably supported and in which an introduction channel 20a is formed which introduces a fluid to the vane 4. The introduction channel 20a comprises a nozzle sheet 24 which guides a fluid flowing into the wing 4, and a support member 25 which is provided in the upstream side of the nozzle sheet 24 and which supports wall surfaces of the introduction channel 20a, the wall surfaces being mutually opposed to each other Support element 25 has a wing shape in a cross-sectional view.

Description

Technical area

The present invention relates to a radial gas relaxation device (radial flow gas relaxation device) in which vanes are arranged on a single shaft in multiple stages.

It will be the priority of Japanese Patent Application No. 2011-190525 filed Sep. 1, 2011, the contents of which are incorporated herein by reference.

State of the art

The gas relaxation device is used to suck and relax a high-pressure gas discharged from a power plant, convert a pressure energy of the gas into a velocity energy (mechanical energy), and thus recover energy and reduce the power of a drive motor or the like.

In recent years, a gas relaxation has been required, which corresponds to higher pressure energy. As such a gas relaxation device, a radial gas relaxation device is known in which a plurality of vanes are provided in multiple stages. As an example of the centrifugal gas relaxation device, there is known a radial gas relaxer having a transmission (speed increasing gear) composed of a driving gear, a speed increasing gear composed of a gear meshing with the driving gear, and a plurality of blades attached to one Gear shaft are arranged (for example, refer to Patent Document 1).

In addition, a radial gas relaxation device is also known, in which the plurality of vanes between bearing rollers is arranged on a single shaft, and the vanes are installed in a single housing. In the radial gas relaxation device, where the plurality of vanes are disposed on the single shaft, the shaft is a single shaft rather than comprising the multi-stage blade. Thus, as compared with the transmission type centrifugal gas relaxation apparatus or the like, the number of high pressure seals or the high pressure housing can be minimized, and a high reliability radial expansion valve can be realized even in a higher pressure state (for example, referring to Patent Document 2).

As in 5 and 6 shown includes a Radialgasentspanner 101 According to the prior art, a housing 2 , a rotary shaft 3 , which rotate in the housing 2 is provided, and a variety of wings 4 at the rotary shaft 3 are fixed.

The Radialgasentspanner 101 includes two gas relaxation sections 105a and 105b to relax the gas in the interior section of the gas relaxation device. The housing 2 is from a case main body 6 and a diaphragm group 7 composed of a plurality of diaphragms in the housing main body 6 are installed, and are integrally connected. The gas relaxation sections 105a and 105b can have a variety of diaphragms 8th . 9a . 9b . 10a . 10b . 11a . 11b . 12a . 12b . 13a and 13b connect, in which return bends connecting stages are formed in an axial direction.

The relaxation section 105a and 105b includes gas introduction channels 120a and 120b that with intake ports 18a and 18b of the housing 2 communicate, and Gasausströmkanäle 21a and 21b that with ejection orifices 19a and 19b of the housing 2 communicate in each section.

Among these are the gas introduction channels 120a and 120b between the mid-diaphragm 8th which is defined in the middle between two gas relaxation sections 105a and 105b and diaphragms 9a and 9b are provided, which among the plurality of diaphragms except the central diaphragm 8th are closest to the middle.

jet leaves 24 that has a gas flow according to profiles of the wings 4 are on the upstream side of the wings 4 at the gas introduction channel 120 intended.

In the radial gas release 101 With the above construction, after that is over the intake port 18a gas introduced from a power plant (not shown) in a gas relaxation section 105a the gas is released to the other gas relaxation section 105b over gas pipes 22 and the intake port 18b introduced, and will continue to relax.

However, in Radialgasentspanner 101 according to the prior art, to channel widths of Gaseinführkanals 120a and the gas introduction channel 120b to secure, spacers 125 in the upstream sides of the nozzle blades 24 the gas introduction channels 120a and 120b Installed.

Documents according to the prior art

Patent document

• Patent Document 1: Japanese Patent No. 3457828
• Patent Document 2: Untested Japanese Patent Application, First Publication Number 2011-43070

Subject of the invention

Problems to be solved by the invention

However, after the spacers 125 in the upstream sides of the nozzle blades 24 are installed, there is a problem that a flow of in the nozzle blades 24 flowing gas is disturbed. As in 6 shown when a flow line L of the introduced gas through the spacers 125 is disturbed, a loss occurs when the gas enters the nozzle blades 24 flows. In addition, after placing the spacers in the vicinity of the inlets of the gas introduction channels 120a and 120b are installed, reduction effects of an insertion passage width change due to a pressure difference are reduced. Thus, a gas flow rate is changed in accordance with the change of the channel width, a desired gas flow rate is not generated when the gas enters the nozzle blades 24 flows, and a loss occurs. In this way obstruct the spacers 125 a relaxation performance of the wings 4 , and in addition, a reduction in the performance of the Radialgasentspanners occurs 101 on.

The present invention has been made in consideration of the above-described circumstances, and an object thereof is to provide a centrifugal gas relaxation device capable of achieving a desired performance. In addition, it is an object of this to provide a radial gas relaxation device of the channel widths of the gas introduction channels 120a and 120b and walls of the diaphragms that form the housing prevent them from being deformed.

Means of solving the problems

In order to achieve the objects described above, the present invention provides the following means.

According to a first aspect of the present invention, a centrifugal gas relaxation apparatus comprises: a rotating shaft, a vane fixed to the rotating shaft, and a housing by which the rotating shaft is rotatably supported and in which an introducing passage leading fluid to the vane is formed , In addition, the insertion channel includes: a nozzle blade that guides a fluid flowing into the wing, and a support member that is provided in an upstream side of the nozzle blade and supports the wall surfaces of the introduction channel, the channel surfaces being mutually opposed. In addition, the support element has a wing shape in cross-sectional view.

According to this structure, distances from lower ends of the mutually opposing wall surfaces of the insertion channel provided in the housing due to the support member are shortened to support points, a deformation amount of the opposing wall surfaces can be reduced, and a desired channel width can be secured. Moreover, after the support member is formed in a cross-sectional view in the wing shape, the flow of the fluid flowing in the nozzle blade can be prevented from being disturbed.

Moreover, according to a second aspect of the present invention, a radial-gas relaxation apparatus comprises: a rotating shaft, two groups of blade groups composed of blades fixed to the rotating shaft and provided symmetrically in an axial direction, and a housing through which the Rotary shafts is rotatably supported, and in which a first insertion channel, which introduces a fluid to the wing group of the first group, and a second insertion channel, which is provided adjacent to the first insertion channel and introduces the ejected from the wing group of the first group fluid to the wing group of the second group , are formed. Moreover, the second insertion channel includes: a nozzle blade that guides a fluid flowing into the blade, and a support member provided in an upstream side of the nozzle blade and supporting wall surfaces of the second insertion channel, the wall surfaces mutually opposed, and the support member in FIG a cross-sectional view has a wing shape.

According to this structure, a desired channel width can be ensured in the first insertion channel and the second insertion channel. Moreover, even if a pressure difference between the fluid flowing into the first insertion channel and the fluid flowing into the second insertion channel is large, the deformation amounts of a center wall and the mutually opposing wall surfaces of the second insertion channel due to the support member can be reduced, and after the support member in FIG is formed in a cross-sectional view in a wing shape, the flow of the fluid flowing in the nozzle sheet can be prevented from being disturbed.

According to a third aspect of the present invention, a plurality of support members are provided around the rotation shaft, and a width of the support member is formed so as to be stepped in a radial direction from an outer periphery is narrowed to an inner circumference such that gaps between the support members in the radial direction are the same.

According to this structure, the fluid passing through the vicinity of the support member can be smoothly introduced to the nozzle blade without increasing the flow rate of the fluid.

Moreover, according to a fourth aspect of the present invention, the housing includes a housing main body and a plurality of diaphragms installed in the housing main body and integrally connected. The insertion channel is formed in the plurality of diaphragms.

According to this structure, the housing can be easily assembled on which the nozzle blade and the support member formed in a vane shape are inserted. In addition, maintenance of an interior section can be easily performed.

Effect of the invention

According to the present invention, a radial gas relaxation device can be provided which achieves a desired performance and can reduce the deformation amount of the wall of the diaphragm forming the housing.

Brief description of the drawings

1 FIG. 10 is a cross-sectional view of a radial-gas relaxation device according to an embodiment of the present invention. FIG.

2 is an enlarged view of a section A of 1 ,

3 is one of B of 2 considered view.

4 FIG. 13 is a view showing a streamline of a gas flowing around the support sheet. FIG.

5 FIG. 10 is a cross-sectional view of a prior art radial gas spreader. FIG.

6 is from C of 5 looked at a view, and is a view showing a flow line of a gas flowing around a spacer.

Description of the embodiments

An embodiment of the present invention will be described in detail with reference to the drawings.

As in 1 and 2 shown includes a Radialgasentspanner 1 According to the embodiment of the present invention, a tubular housing 2 , a rotary shaft 3 on the case 2 is rotatably supported and in an axial direction of the housing 2 extends, and a variety of wings 4 at the rotary shaft 3 are fixed.

In addition, in the following description, the axial direction of the housing coincides 2 with the axial direction of the rotary shaft 3 , In addition, the axial direction of the housing 2 and the axial direction of the rotary shaft 3 simply referred to as axial direction.

The Radialgasentspanner 1 includes two sections to expand a gas in the inner section. This means the radial gas relaxation 1 includes two gas relaxation sections 5a and 5b that comes from a gas relaxation section 5a disposed in a first side of the axial direction and a gas releaser section 5b which is arranged in a second side of the axial direction, are composed.

The Radialgasentspanner 1 of the present embodiment has a structure that provides a rotational driving force through the first gas relaxation section 5a and receives a rotational driving force by introducing the expanded gas from the first gas relaxation section 5a to the second gas relaxation section 5b was ejected.

The housing 2 includes a housing main body 6 and a diaphragm group 7 located in the interior portion of the housing main body 6 is provided. The diaphragm group 7 is from eleven diaphragms 8th . 9a . 9b . 10a . 10b . 11a . 11b . 12a . 12b . 13a . 13b assembled, which are constructed so that they can be pulled out in the axial direction.

The first gas release section 5a includes the diaphragm 8th , which is located in the middle, and the diaphragms 9a . 10a . 11a . 12a and 13a placed in a first side of the diaphragm 8th are connected. In addition, the second gas relaxation section includes 5b the diaphragm 8th , which is located in the middle, and the diaphragms 9b . 10b . 11b . 12b and 13b placed in a second side of the diaphragm 8th are connected.

That means two gas relaxation sections 5a and 5b have the central diaphragm 8th as a common component.

An intake port 18a for introducing the gas to the first gas relaxation section 5a and a suction port 18b for introducing the gas to the second gas relaxation section 5b are in the housing main body 6 educated.

In addition, an ejection orifice 19a for discharging the gas from the first gas relaxation section 5a and an ejection orifice 19b for discharging the gas from the second gas relaxation section 5b in the housing main body 6 educated.

In addition, the ejection orifice 19a the first gas release section 5a and the intake port 18b the second gas relaxation section 5b through a gas pipe 22 connected.

The rotary shaft 3 is arranged to be the center of the diaphragm group 7 penetrates. Both end portions of the rotary shaft 3 are through diaphragms 13a and 13b worn, which end plates each of the two Gasentspannersektionen 5a and 5b are rotatable about bearings 15 , In addition, dry gas seals 16 in the inner peripheries of the diaphragms 13a and 13b provided within each storage 15 are positioned.

The variety of wings 4 is at the rotary shaft 3 fixed, and wings 4 the first gas relaxation section 5a forming four steps and wings 4 the second gas relaxation section 5b forming four stages are arranged so that they face each other.

In every wing 4 are when the opening portion, extending in the radial direction of the wing 4 opens to the outer periphery, to an inlet mouth 49 is set, and the opening portion which opens to the axial direction, to an ejection orifice 42 is fixed, the wings 4 the first gas relaxation section 5a forming four steps and the wings 4 the second gas relaxation section 5b forming four stages arranged such that the inlet mouths 41 on the sides of the central diaphragm 8th are positioned. That means the wings 4 , which is the first gas relaxation section 5b form, are arranged such that the ejection orifice 42 to the first side of the axial direction, and the wings 4 which the second gas relaxation section 5b form, are arranged such that the ejection orifice 42 to the second side of the axial direction.

In addition, although the same reference numerals to the variety of wings 4 are provided, the sizes of the plurality of wings 4 different from each other. In particular, the sizes of the plurality of wings 4 changed to accommodate a relaxation stroke of the gas.

A first insertion channel 20a and a second insertion channel 20b that with the intake ports 18a and 18b communicate accordingly, are between the diaphragms 9a and 9b formed in both sides of the central diaphragm 8th are positioned. This means the first insertion channel 20a the first gas release section 5a is between a wall surface 85 the first side of the central diaphragm 8th and a wall surface 91 the second side of the diaphragm 9a educated. In addition, the second insertion channel 20b the second gas relaxation section 5b between a wall surface 82 the second side of the central diaphragm 8th and a wall surface 92 the first side of the diaphragm 9b educated.

Accordingly, the first introduction channel 20a and the second insertion channel 20b arranged so that they pass over the central diaphragm 8th adjacent to each other.

Similar are outlet channels 21a and 21b , which correspond to the previously described ejection orifices 19a and 19b communicate between the diaphragms 13a and 13b , which are end plates, and those adjacent to the diaphragms 13a and 13b arranged diaphragms 12a and 12b educated.

Among these, the outlet channel communicates 21a the first gas release section 5a with the discharge mouth 19a of the housing main body 6 , and the outlet chamber 21b the second gas relaxation section 5b communicates with the discharge mouth 19b of the housing main body 6 ,

A variety of nozzle sheets 24 that the inflow of the gas to the wings 4 lead is in the upstream sides of the wings 4 in both the first insertion channel 20a as well as the second insertion channel 20b intended. In the following embodiment, there are 17 nozzle blades 24 intended.

As in 3 the nozzle blades are shown 24 arranged at equal intervals in the circumferential direction. Each nozzle sheet 24 has a wing shape, when viewed in the axial direction in cross-section, a leading edge is round and an outlet edge is pointed. In addition, in the nozzle blades 24 the leading edges are arranged in the circumferential direction in the outer peripheral side of the diaphragm, the discharge edges are arranged in the inner peripheral side of the diaphragm in the circumferential direction, and the nozzle blades 24 are inclined in a direction of rotation R with respect to the guide edges arranged such that the outlet edges along the direction of rotation R of the rotary shaft 3 are. That is, front ends are arranged in the upstream of the flow direction of the gas, and rear ends are disposed in the downstream.

In addition, for example, the cross-sectional shape of the nozzle sheet 24 under use determined by a numerical fluid mechanics (CFD) analysis. Accordingly, the cross-sectional shape of the nozzle sheet becomes 24 of the present embodiment is formed so as to be asymmetric with respect to a center line along the flow direction (hereinafter, referred to as a streamline direction) of the gas. This means the nozzle sheet 24 has a shape that the flow of the gas gently to the wings 4 Introduces to promote an operation that the gas in the wings 4 relaxed and accelerated.

A variety (seventeen leaves) of the support sheets 25 , which are support members, are in the wider outer peripheral side of the nozzle sheet 24 intended. Similar to the nozzle blades 24 are the support sheets 25 arranged at equal intervals in the circumferential direction. Each support sheet 25 has a so-called wing shape, in which viewed in the axial direction in a cross-sectional shape, a leading edge is round and an outlet edge is pointed. In addition, in the support sheets 25 the leading edges are arranged in the circumferential direction in the outer peripheral side of the diaphragm, the discharge edges are arranged in the circumferential sides of the diaphragm in the circumferential direction, and the support blades 25 are arranged in the direction of rotation inclined in the direction of rotation R with respect to the leading edges such that the outlet edges along the direction of rotation R are befindlich. That means in the support sheets 25 For example, the front ends are arranged in the upstream of the streamline direction, and the rear ends are located in the downstream.

In addition, the shapes of the support sheets 25 formed such that a width of the support sheet 25 is gradually tapered in the radial direction from the outer circumference to the inner circumference. In addition, gaps W are between the support sheets 25 in the streamline direction, that is, the radial direction, approximately equal.

In addition, the cross-sectional shape of the support sheet 25 from that of the nozzle sheet 24 different and is formed symmetrically along the streamline direction with respect to the center line. The shape, the position in the circumferential direction and the position in the radial direction of the support sheet 25 are also determined using CFD or the like in the nozzle blades 24 As little as possible to influence introduced gas, and it is particularly preferred that the shape of the support sheet has a shape along the streamline. Moreover, it is preferable that the length in the streamline direction be set with a range in which the influence of the streamline is small (which does not disturb the streamline), and shortened as much as possible. In addition, after the streamline is changed according to a flow rate of the gas, it is preferable that the flow rate is appropriately determined according to the conditions of use.

In the intermediate diaphragms 9a . 10a . 11a . 12a . 9b . 10b . 11b and 12b in each of the gas relaxation sections 5a and 5b is a return curvature (intermediate channel) 27 formed with a U-shaped cross section, which the ejection orifice 42 of the grand piano 4 in the previous stage and the inlet mouth 41 of the grand piano 4 connects in the following stage. Seventeen leaves of return wings 28 are in the return curvature 27 provided such that the gas flow to the nozzle sheet 24 that is in the upstream side of the wing 4 is positioned, and the inlet mouth of the wing 4 is efficient in the subsequent stage.

An operation of the Radialgasentspanners 1 The structure described above will be explained. First, the high temperature and high pressure gas from a particular power plant is delivered via the intake port 18a to the first gas relaxation section 5a introduced. In the first gas release section 5a The suction and relaxation are over four stages through the wings 4 the four stages repeated, and the gas is from the ejection orifice 19a pushed out. Subsequently, the gas passes through the gas pipe 22 and the intake port 18b to the second gas relaxation section 5b introduced in the second gas relaxation section 5b relaxes and gets off the muzzle 19b pushed out.

The inflowing gas flows in the axial direction in the inner portion of the two Gasentspannersektion 5a and 5b , However, according to the structure described above, the gas flows in the mutually opposite directions. This means that the gas flows in the gas relaxation section 5a from the second side of the axial direction to the first side of the axial direction. In addition, the gas flows in the Gasentspannersektion 5b from the first side of the axial direction to the second side of the axial direction.

Here is, compared with the pressure of the gas, that over the intake port 18a in the first insertion channel 20a is introduced, the pressure of the gas passing through the intake port 18b to the second insertion channel 20b is introduced, low. This means the pressure difference between the pressures in the first insertion channel 20a and in the second insertion channel 20b passing over the diaphragm 8th adjacent to each other is increased.

According to the embodiment described above, the pressure difference between the pressure in the first introduction channel 20a and the pressure in the second insertion channel 20b increases, and even if a force of an order of magnitude, which is a deformation of the diaphragm 8th caused on between the first insertion channel 20a and the second insertion channel 20b trained, central diaphragm 8th can be applied, a deformation size by providing the support sheets 25 be reduced. In addition, the support sheet 25 formed in a cross-sectional view in a wing shape, and thus, as in 4 shown a disturbance of the streamline L of the support sheets 25 flowing gas can be reduced.

In addition, the shapes of the support sheets 25 formed such that a width of the support sheet 25 is gradually tapered from the outer circumference in the radial direction to the inner circumference. In addition, gaps W are between the support sheets 25 same in the radial direction. As a result, this may be due to the environments of the support sheets 25 passing gas gently to the nozzle blade 24 be introduced without requiring an increase in the flow rate of the gas.

In addition, after the support sheet 25 has a shape that is symmetrical in the streamline direction, the support sheets can be made easier.

In addition, after the variety of diaphragm groups 7 that the case 2 can be divided in the axial direction, maintenance in the inner portion can be easily performed.

In addition, the technical scope of the present invention is not limited to the above-described embodiments, and various modifications may be made within a range that does not depart from the gist of the present invention. For example, the support sheet 25 have an asymmetrical shape in the streamline direction.

Industrial Applicability

According to the radial gas relaxation device of the present invention, a desired performance is obtained, and the deformation amount of the wall of the diaphragm forming the housing can be reduced.

LIST OF REFERENCE NUMBERS

1

Radial gas expander

2

casing

3

rotary shaft

4

wing

5

Gasentspannersektion

6

Housing main body

7

Diaphragmagruppe

8, 9a, 9b, 10a, 10b, 11a, 11b, 12a, 12b, 13a, 13b

diaphragm

20a

first insertion channel (insertion channel)

20b

second insertion channel (insertion channel)

24

nozzle sheet

25

Supporting blade (supporting element)

27

Return bend

28

Return vanes

Claims (4)

Radial gas relaxation device, comprising: a rotary shaft, a wing which is fixed to the rotary shaft, and a housing by which the rotary shaft is rotatably supported and in which an insertion channel is formed, which introduces a fluid to the wing, wherein the insertion channel comprises: a nozzle blade which carries a fluid flowing in the wing, and a support member provided in an upstream side of the nozzle sheet and supporting the wall surfaces of the insertion channel, the wall surfaces being mutually opposed, and wherein the support member has a wing shape in a cross-sectional view. Radial gas relaxation device, comprising: a rotary shaft, two groups of wing groups composed of wings fixed to the rotating shaft and symmetrically provided in an axial direction, and a housing, by which the rotary shaft is rotatably supported, and in which a first insertion channel, which introduces a fluid to the wing group of a first group, and a second insertion channel, which is provided adjacent to the first insertion channel and that of the wing group of the first group ejected fluid to a wing group of a second group, wherein the second insertion channel comprises: a nozzle blade which carries a fluid flowing in the wing, and a support member provided in an upstream side of the nozzle blade and supporting wall surfaces of the second insertion channel, the wall surfaces being mutually opposed, and wherein the support member has a wing shape in a cross-sectional view. A radial-gas relaxation device according to claim 1 or 2, wherein a plurality of the support members are provided around the rotation shaft, and a width of the support member is gradually tapered from an outer periphery in a radial direction to an inner periphery such that gaps between the support members in the radial direction are equal. A radial gas relaxation device according to any one of claims 1 to 3, wherein said housing has a housing main body and a plurality of diaphragms installed in said housing main body and integrally connected, and wherein said insertion channel is formed between said diaphragms.

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