JP2011078874A - Moisture separator and cooling machine - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a moisture separator capable of collecting even small droplets effectively with minimized pressure loss and a cooling machine equipped with it. <P>SOLUTION: The moisture separator 10 includes the first moisture recovery pocket 20 arranged inside bent parts 11A and 11B in a passage 11 and opened from the bent parts 11A and 11B to the upstream side, and the width of the passage 11 is narrower at the position of the first moisture recovery pocket 20 than the upstream and downstream sides of the passage 11 with respect to the first moisture recovery pocket 20. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a moisture separator that separates moisture contained in a gas and a cooler equipped with the moisture separator.

  A cooler is mounted on the front stage of the compressor for the purpose of improving performance, and the gas is cooled and then introduced into the compressor. In such a cooler, when the gas is cooled, droplets are formed by moisture contained in the gas, and when the gas containing such droplets is introduced into the compressor, the droplets There is a risk of problems such as erosion. For this reason, the cooler is provided with a moisture separator, and the cooled gas is discharged from the cooler after the moisture contained by the moisture separator is removed.

Specifically, as the moisture separator, a plurality of bone plates are arranged in parallel to form a flow path that bends in a zigzag manner between the bone plates, and is bent in a zigzag shape when viewed from the upstream side of the flow channel. One having a droplet collection pocket that opens to a side wall portion that extends from the apex of a valley-shaped bent portion that bulges to the outside of the channel to the apex of a mountain-side bent portion that bulges to the inside of the channel has been proposed ( For example, see Patent Document 1).
In such a moisture separator, when the gas passes through the zigzag flow path between the bone plates, the gas collides with a side wall portion extending from the apex of the valley-shaped bent portion to the apex of the mountain-shaped bent portion. At that time, since the droplet collection pocket is opened in the side wall portion, a part of the droplet contained in the gas enters the droplet collection pocket and is collected. .

As another example, a plurality of corrugated plates are juxtaposed to form a flow path, and these corrugated plates narrow the interval between the corrugated plates and increase the flow velocity of the fluid, There has been proposed one including a wall surface against which gas collides on the downstream side of the throttle portion (see, for example, Patent Document 2).
In such a moisture separator, it is said that droplets contained in the gas can be collected by increasing the flow velocity at the throttle and passing through and colliding with the downstream wall surface.

JP 2003-144824 A JP 2009-125672 A

However, in the moisture separator as in Patent Document 1, only a part flowing in the vicinity of the side wall portion can collect droplets in the flowing gas. In particular, when the contained droplets are small, the inertial force that acts when changing the direction of the flow is small and it is easy to flow along the flow path, so it is not possible to collect the droplets effectively. It was.
In addition, in the moisture separator as in Patent Document 2, since the flow velocity is increased at the throttle portion, even a small droplet can easily collide with the wall surface. However, a liquid in which gas continuously flowing along the wall surface adheres to the wall surface The droplets were collected again, and the droplets could not be collected effectively. In order to effectively collect even small droplets, the gap between the corrugated plates in the throttle portion is narrowed in order to further increase the flow velocity, resulting in an increase in pressure loss.

  The present invention has been made in view of the above-described circumstances, and includes a moisture separator that can effectively collect even a small droplet with minimal pressure loss, and the same. A cooler is provided.

In order to solve the above problems, the present invention proposes the following means.
The present invention is a moisture separator comprising a flow path formed in a meandering manner by a plurality of curved portions and through which a gas containing moisture flows, and is provided inside the curved portion of the flow path, A first moisture collection pocket that opens toward the upstream side from the curved portion, and the width of the flow path is narrower than the upstream side and the downstream side of the moisture collection pocket at the position of the moisture collection pocket. It is characterized by being formed.

  According to this structure, the flow path formed in the meandering shape has a width at a position where the first moisture collection pocket provided inside the curved portion is provided, on the upstream side and the downstream side of the position. It is narrower than each width. For this reason, when the gas flowing through the flow path passes through the curved portion, it accelerates at the position where the first moisture pocket is provided, and on the downstream side of the position, the outside of the curved portion due to inertia, That is, it flows toward the inside of the curved portion located on the downstream side. And since the 1st moisture collection pocket is similarly provided in the inner side of this curved part located in the downstream side, and it is opening toward the upstream side, the gas accelerated on the upstream side is made the first It is possible to effectively flow into the moisture collection pocket. Similarly, the first moisture collection pocket is provided in each curved portion, so that the acceleration at the position of the first moisture collection pocket and the liquid in the next first moisture collection pocket are performed. The droplet collection is repeated, and moisture can be effectively separated from the gas.

  The moisture separator preferably further includes a second moisture collection pocket that is provided outside the curved portion of the flow path and opens from the curved portion toward the upstream side.

  According to this configuration, the second moisture collection pocket that opens from the curved portion toward the upstream side is provided outside the curved portion of the flow path, so that the first moisture collection of the curved portion is performed. The gas that is accelerated at the position of the pocket and flows outward can flow into the second moisture collection pocket to collect the droplets, and moisture can be separated more effectively.

  Further, in the moisture separator, a plate-like member formed in a meandering manner is provided with a plurality of intervals, and the blade plate having the passage between each other is fixed to the blade plate. And a projecting member that projects toward the upstream side of the flow path and forms the first moisture collection pocket with the blade.

  According to this configuration, the configuration of the flow path and the first moisture collection pocket as described above is easily constructed by the plurality of blades formed in a meandering manner and the protruding member fixed to the blades. be able to.

  The moisture separator preferably includes a position adjusting mechanism for moving the adjacent blade plates relative to each other along the direction in which the blade plates are disposed.

  According to this configuration, the distance between the blades adjacent to each other, that is, the width of the flow path can be adjusted by moving the blades adjacent to each other along the arrangement direction of the blades by the position adjusting mechanism. For this reason, it is possible to adjust the balance between the droplet collection effect and the pressure loss brought about by narrowing the width of the flow path, and according to the operating environment such as the gas pressure, the gas flow velocity, the target recovered droplet diameter, etc. , Gas moisture can be separated under optimum conditions.

  Further, the present invention is characterized by comprising the moisture separator described above and a heat exchanger that performs heat exchange with the gas, cools the gas, and sends the gas to the moisture separator.

  According to this configuration, moisture contained in the gas cooled by the heat exchanger can be effectively separated by the moisture separator.

According to the moisture separator of the present invention, even a small droplet can be effectively collected with a minimum pressure loss.
According to the cooler of the present invention, it is possible to obtain a dried cooling gas in which moisture is effectively separated by the moisture separator.

It is a top view of the gas cooler of the 1st Embodiment of this invention. It is sectional drawing seen from the central-axis direction of the gas cooler of the 1st Embodiment of this invention. It is the perspective view which fractured | ruptured a part of moisture separator of the 1st Embodiment of this invention. It is sectional drawing fractured | ruptured along the flow path of the moisture separator of the 1st Embodiment of this invention. It is sectional drawing fractured | ruptured along the flow path of the moisture separator of the 2nd Embodiment of this invention. It is sectional drawing fractured | ruptured along the flow path of the moisture separator of a comparative example. It is a graph which shows the relationship between the droplet diameter calculated | required by CFD analysis about the moisture separator of an Example and a comparative example, and a droplet discharge rate. It is a figure which shows the flow state of the droplet calculated | required by CFD analysis about the moisture separator of Example 1 of this invention. It is a figure which shows the flow state of the droplet calculated | required by CFD analysis about the moisture separator of Example 2 of this invention. It is a figure which shows the flow state of the droplet calculated | required by CFD analysis about the moisture separator of the comparative example. It is the perspective view which fractured | ruptured a part of moisture separator of the 3rd Embodiment of this invention. It is sectional drawing fractured | ruptured along the flow path of the moisture separator of the 3rd Embodiment of this invention.

(First embodiment)
A first embodiment according to the present invention will be described below with reference to the drawings. FIG.1 and FIG.2 has shown the gas cooler provided with the moisture separator of the 1st Embodiment of this invention. A gas cooler 1 that is a cooler of the present embodiment is for cooling the supply air of a compressor, for example, and is connected to an intake portion of the compressor (not shown). As shown in FIGS. 1 and 2, the gas cooler 1 includes a substantially cylindrical casing 2 closed at both ends, an air supply duct 3 for supplying a gas to be cooled into the casing 2, and a casing 2. The exhaust duct 4 that exhausts the gas G cooled from the inside, the heat exchanger 5 that cools the gas G that is distributed inside the casing 2, and the moisture of the gas G cooled by the heat exchanger 5 are separated. And a moisture separator 10 to be provided. The casing 2 is disposed so that the center axis L <b> 2 is substantially horizontal. In addition, the air supply duct 3 and the exhaust duct 4 are respectively provided at the upper part of the outer peripheral surface of the casing 2 and, for example, both end portions 2a and 2b along the central axis L2 and both sides sandwiching the central axis L2. Further, they are arranged so as to be displaced from each other.

  Further, as shown in FIG. 2, the heat exchanger 5 is disposed along the central axis L <b> 2 substantially at the center of the casing 2 as viewed in the direction along the central axis L <b> 2, and opens on both sides with the central axis L <b> 2 interposed therebetween. . The heat exchanger 5 has a large number of cooling pipes 5a arranged with a gap therebetween and substantially parallel to the central axis L2, and the cooling pipes 5a forming a pair are U-shaped on the other end 2b side. One end is connected to a cooling water supply unit (not shown) that supplies cooling water, and the other is connected to a cooling water recovery unit (not shown) that collects cooling water. A moisture separator 10 is connected to the opening on the exhaust duct 4 side of the heat exchanger 5. A partition wall 6 is provided between the heat exchanger 5 and the inner peripheral surface of the casing 2 above the heat exchanger 5 to separate the air supply duct 3 side and the exhaust duct 4 side. For this reason, the gas G supplied into the casing 2 from the air supply duct 3 flows into the heat exchanger 5 from the opening on the air supply duct 3 side, and is cooled when flowing between the cooling pipes 5a. It is cooled by cooling water flowing through the inside of the pipe 5a. The gas G cooled by the heat exchanger 5 and flowing out from the opening on the exhaust duct 4 side is discharged from the exhaust duct 4 after the moisture is separated by the moisture separator 10.

Next, the detail of the structure of the moisture separator 10 is demonstrated.
As shown in FIG. 3, the moisture separator 10 of the present embodiment is a substantially plate-like member, and a plurality of the moisture separators 10 are arranged with a space between each other, and a blade 11 having a flow path 11 between each other, Support plates 13 and 14 are provided on both side edges 12 a and 12 b of the plate 12 to support the blade plate 12 and close the side portions of the flow path 11. The moisture separator 10 is arranged so that the one end 12c side of the blade 12 is directed to the heat exchanger 5 and the one side edge 12a is on the lower side, whereby the heat exchanger 5 is arranged. The gas G cooled in step S12 flows into the flow path 11 between the blades 12 from one end 12c side of the blade plate 12, flows out from the other end 12b side, and is separated from the gas G in the flow channel 11. The formed droplet D travels through the blade plate 12 and is collected on the support plate 13 on the side edge 12a side. A drain tube 15 is connected to the support plate 13 on the one side edge 12a side, and the collected droplet D can be discharged.

  As shown in FIG. 4, spacers 16 and 17 are provided at both ends 12 c and 12 d of the blade 12, and the blades 12 are spaced between the support plates 13 and 14 by the spacers 16 and 17. Also in the intermediate portion, the width of the flow path 11 is fixed to be uniform. Further, the blade 12 has a plurality of bent portions 12e and is formed in a zigzag shape, whereby the flow path 11 between the blade plates 12 also has a plurality of curved portions 11A and 11B in a zigzag shape. Is formed. In the present embodiment, each vane plate 12 has two bent portions 12e, so that a flow path 11 having two curved portions 11A and 11B is formed. Further, in the wing plate 12, a substantially plate-like first projecting member 18 projecting toward the upstream side is provided on a surface 12h on the downstream side of the mountain folding side 12f of the folded portion 12e. The base end of the first projecting member 18 is fixed to the surface 12h by welding or the like, for example. And the 1st protrusion member 18 protrudes so that it may space apart from the blade board 12 gradually toward the upstream from the folding part 12e. Further, the first projecting member 18 is bent toward the side close to the blade 12 on the tip side, and is formed in a generally U shape as a whole. The first protruding member 18 forms a first moisture collection pocket 20 that opens toward the upstream side from the curved portions 11A and 11B between the first protruding member 18 and the blade plate 12. The first protrusion member 18 that forms the first moisture collection pocket 20 has a width B <b> 1 at the position of the first moisture collection pocket 20 corresponding to the interval between the blades 12. The moisture collection pocket 20 is formed so as to be narrower than the widths B2 and B3 on the upstream side and the downstream side.

  Further, in the present embodiment, outside the curved portion 11B on the downstream side of the flow path 11, it is fixed to the downstream surface 12j of the valley folding side 12g of the folded portion 12e of the vane plate 12, and the upstream surface 12h. And a second projecting member 19 disposed substantially in parallel. And by this 2nd protrusion member 19, the 2nd moisture collection pocket opened toward the upstream in the outer side of the curved part 11B of the flow path 11 between the 2nd protrusion member 19 and the blade 12 21 is formed.

Next, the operation of the moisture separator 10 of this embodiment and the gas cooler 1 provided with the moisture separator 10 will be described.
As shown in FIG. 4, in the gas cooler 1, the gas G cooled by the heat exchanger 5 flows into the flow path 11 from the inlet 10 a on the one end 12 c side of the blade plate 12 and flows in a zigzag shape. It flows out from the outlet 10b on the other end 12b side of the plate 12. Here, the width B1 of the flow path 11 at the position where the first moisture collection pocket 20 is provided is narrower than the widths B2 and B3 of the flow path 11 on the upstream side and the downstream side of the position, respectively. ing. For this reason, the gas G flowing through the flow path 11 is accelerated at the position where the first moisture collection pocket 20 is provided when passing through the curved portion 11A on the upstream side, and becomes wider than the position. On the downstream side, the droplet D contained in the gas G flows toward the outside of the curved portions 11A and 11B, that is, the inside of the curved portion 11B located on the downstream side due to inertia. And since the 1st moisture collection pocket 20 is similarly provided in the inner side of this curved part 11B located in the downstream, and it is opening toward the upstream, the droplet D accelerated on the upstream side Can effectively flow into the first moisture collection pocket 20. For this reason, even a small droplet D can be effectively collected with a minimum pressure loss, and therefore it is possible to reduce the size. In addition, in this embodiment, although the flow path 11 shall be provided with the two curved parts 11A and 11B, it is not restricted to this, It is good also as a thing provided with three or more curved parts. Similarly, the first moisture collection pocket 20 is provided in each curved portion, so that the acceleration at the position of the first moisture collection pocket 20 and the next first moisture collection pocket 20 are performed. In this case, the collection of the droplets D is repeatedly performed, and moisture can be effectively separated from the gas G.

  Furthermore, in the present embodiment, the second moisture collection pocket 21 that opens toward the upstream side from the curved portion 11B is provided outside the curved portion 11B of the flow path 11, so that the first portion of the curved portion 11B is provided. The gas G that is accelerated at the position of the one moisture collection pocket 20 and flows outward can flow into the second moisture collection pocket 21 to collect the droplets D, so that the moisture can be collected more effectively. Separation of minutes can be performed. Moreover, in the moisture separator 10 of this embodiment, each structure of the flow path 11, the 1st moisture collection pocket 20, and the 2nd moisture collection pocket 21 is made into the some blade 12 formed in the zigzag shape. And the first projecting member 18 and the second projecting member 19 fixed to the blade 12 can be easily constructed. And in the gas cooler 1 provided with such a moisture separator 10, the moisture contained in the gas G cooled by the heat exchanger 5 can be effectively separated to obtain a dried gas G, and the whole As a result, downsizing can be achieved.

(Second Embodiment)
Next, a second embodiment of the present invention will be described. FIG. 5 shows a second embodiment of the present invention. In this embodiment, the same members as those used in the above-described embodiment are denoted by the same reference numerals, and the description thereof is omitted.

  As shown in FIG. 5, the moisture separator 30 of the present embodiment includes a blade plate 32 that is a substantially plate-like member and is provided with a plurality of gaps spaced apart from each other and having a flow path 31 therebetween. Although not shown, it is similarly supported by support plates 13 and 14. The vane plate 32 of the present embodiment has four bent portions 32a, so that a flow path 31 having four curved portions 31A, 31B, 31C, and 31D is formed. Similarly, in the wing plate 32, a substantially plate-like first projecting member 33 projecting toward the upstream side is provided on a downstream surface 32d of the mountain folding side 32b of the folded portion 32a. The first projecting member 33 projects from the bent portion 32a of the blade plate 32 toward the upstream side, bends toward the side close to the blade plate 12 at the tip side, and is disposed along the upstream surface. As a whole, it is formed in a substantially square shape. And the 1st moisture recovery pocket which opens toward the upstream from each of curved part 31A, 31B, 31C, 31D by the 1st protrusion member 33 between the 1st protrusion member 33 and the blade board 32 is provided. 35 is formed, and the flow path 11 has a width B11 at the position of the first moisture collection pocket 35 between the blades 32 by the first projecting member 33 that forms the first moisture collection pocket 35. The first moisture collection pocket 35 corresponding to the interval is formed so as to be narrower than the widths B12 and B13 on the upstream side and the downstream side.

  Also in this embodiment, as in the first embodiment, the width B11 at the position where the first moisture collection pocket 35 provided inside the curved portions 31A, 31B, 31C, 31D is provided is upstream of the position. It is narrower than the respective widths B12 and B13 on the side and downstream side. For this reason, the gas G flowing through the flow path 31 is accelerated at the position where the first moisture collection pocket 35 is provided, for example, when passing through the curved portion 31A, and due to inertia at the downstream side of the position. It flows toward the outside of the curved portion 31A, that is, the inside of the curved portion 31B located on the downstream side. The first moisture collection pocket 35 is similarly provided inside the curved portion 31B located on the downstream side, and is open toward the upstream side. It is possible to effectively flow into one moisture collection pocket 35. Further, the first moisture collection pocket 35 is similarly provided in the curved portions 31C and 31D on the downstream side, so that the acceleration at the position of the first moisture collection pocket 35 and the next first The collection of the droplets D in the one moisture collection pocket 35 is repeated, and the moisture can be effectively separated from the gas G.

In this example, the moisture separator 10 of the first embodiment (hereinafter referred to as Example 1) and the moisture separator 30 of the second embodiment (hereinafter referred to as Example 2) are used as comparative examples. About the conventional moisture separator 100, the collection effect of the droplet D was analyzed by CFD (Computational Fluid Dynams) analysis.
Here, the moisture separator 100 of a comparative example is demonstrated. FIG. 6 shows a moisture separator 100 of a comparative example. As shown in FIG. 6, in the moisture separator 100 of the comparative example, the flow path 101 provided between the blades 102 has three curved portions 101A, 101B, and 101C and is formed in a zigzag shape. On the other hand, the opening 103a of the moisture collection pocket 103 that separates the moisture of the gas G flowing through the flow path 11 is located between the curved portions 101A and 101B and between the curved portions 101B and 101C. It is formed on the wall surface connecting the outer side and the inner side of the curved portion on the downstream side so as to be along the flow path 101, and is provided inside each of the curved portions 101A, 101B, 101C of the flow path 101. It is not configured to open toward the upstream side from 101A, 101B, 101C. Further, the width of the channel 101 is set to be constant. The moisture separator 10 of Example 2 has four curved portions 31A, 31B, 31C, and 31D, and the moisture separator 10 of the comparative example has three curved portions 101A, 101B, and 101C. On the other hand, in the moisture separator 10 of Example 1 shown in FIG. 4, the entire length of the flow path 11 is set short because the flow path 11 has only two curved portions 11A and 11B. ing.

  As described above, the droplet size included in the gas G is 10 for each of the moisture separator 10 of Example 1, the moisture separator 30 of Example 2, and the moisture separator 100 of Comparative Example. CFD analysis was carried out while changing to 15, 20, and 50 μm, and the droplet discharge rate at each droplet diameter, that is, the ratio of the discharged droplet amount to the supplied droplet amount was obtained. FIG. 7 shows the relationship between the droplet diameter and the droplet discharge rate in each example and comparative example, and FIGS. 8 to 10 show the flow of the droplet D for each droplet diameter in each example and comparative example. Indicates the state. 8A to 10B, (a) shows the flow state of the droplet D with a droplet diameter of 20 μm, (b) with a droplet diameter of 15 μm, and (c) with a droplet diameter of 10 μm. . Further, the conditions of the gas G other than the droplet diameter, for example, the gas flow velocity, the gas pressure, and the gas temperature are all the same.

  As shown in FIG. 7, in the moisture separator 10 of Example 1, the droplet discharge rate is 0% when the droplet diameter is 15 μm or more, and the droplet discharge rate is only 1.9% even when the droplet size is 10 μm. The calculation results show that most droplets D are collected when the droplet diameter is 10 μm or more. As shown in FIG. 8, when the flow state of the droplet D is examined in detail, with the droplet diameter of 15 μm or more, first, the first moisture is formed so that the upstreammost curved portion 11A opens to the upstream side. By forming the minute collection pocket 20, many droplets D flow into the first moisture collection pocket 20, and the droplets D contained in the gas G are effectively collected. Recognize.

  Further, the gas G1 containing the droplet D that has not flowed into the first moisture collection pocket 20 at the uppermost stream and the droplet D that has swirled and flowed out in the first moisture collection pocket 20 flows downstream. Will flow. At this time, as shown in FIG. 8, the flow path 11 is narrowed by the first moisture collection pocket 20, so that the gas G containing the droplets D is bent due to inertia due to the increased flow velocity. It can be seen that the flow flows to the outside of the portion 11A, that is, the inside of the next curved portion 11B on the downstream side. In the next curved portion 11B on the downstream side, a first moisture collection pocket 20 that opens toward the upstream side is provided on the inner side, thereby effectively flowing the gas G flowing from the upstream side. Thus, it can be seen that the contained droplet D can be collected.

  Further, the droplet D that did not flow into the first moisture collection pocket 20 and the droplet D that swirled and flowed out in the first moisture collection pocket 20 flow velocity due to the narrow channel 11. It is understood that the liquid is accelerated and flows to the outside of the curved portion 11B and flows into the second moisture collection pocket 21 provided on the outside of the curved portion 11B, whereby the droplet D is collected.

  These tendencies are the same even when the droplet diameter is as small as 10 μm, and only 1.9% of the droplets D are discharged without being collected in the second moisture collection pocket 21. It can be seen that moisture contained in the gas G can be effectively separated.

  Further, as shown in FIG. 7, even in the moisture separator 30 of Example 2, when the droplet diameter is 15 μm or more, most of the droplets D are collected by the first moisture collection pocket 35, The drop discharge rate was calculated to be 0%. As shown in FIG. 9, the first moisture that opens toward the upstream side inside the curved portions 31 </ b> A, 31 </ b> B, 31 </ b> C, and 31 </ b> D also in the moisture separator 30 of the second embodiment as in the first embodiment. It can be seen that the recovery pocket 20 effectively collects the droplets D.

  On the other hand, as shown in FIG. 7, in the moisture separator 100 of the comparative example, the droplet discharge rate becomes high at a droplet diameter of less than 50 μm. From the analysis result shown in FIG. 10, the moisture collection pocket 103 in the moisture separator 100 of the comparative example is not provided in the curved portions 101A, 101B, and 101C, and between the curved portions 101A, 101B, and 101C. The liquid droplets D included in the gas G flowing through the flow channel 101 are less likely to flow into the moisture collection pocket 103 from the opening 103a. Since a large inertia force does not work at each curved portion with respect to the droplet D contained in the gas G flowing through the flow path 101, the width of the gas flows into the moisture collection pocket 103 opened on the wall surface. It is difficult to do.

  As described above, each of the moisture separators 10 according to the first and second embodiments includes the first moisture collection pocket that opens to the upstream side inside the curved portion, and the width of the flow path is the first moisture collection. Since the pocket is formed narrower than the upstream side and the downstream side, the droplets D contained in the gas G can be effectively collected. Furthermore, the moisture separator 10 of the first embodiment further includes the second moisture collection pocket 21 that is provided outside the curved portions 11A and 11B and opens toward the upstream side, so that the droplets D can be more reliably collected. It can be prevented from being collected and discharged. Therefore, compared with the moisture separator 10 of Example 2, the flow path is short, and the droplets D can be collected effectively even if the number of curved portions is small.

(Third embodiment)
Next, a third embodiment of the present invention will be described. 11 and 12 show a second embodiment of the present invention. In this embodiment, the same members as those used in the above-described embodiment are denoted by the same reference numerals, and the description thereof is omitted.

As shown in FIG.11 and FIG.12, the moisture separator 40 of this embodiment is equipped with the structure fundamentally similar to the structure of the moisture separator 10 of 1st Embodiment.
Here, in the present embodiment, one blade plate 12 of the plurality of blade plates 12 is fixed to one of the upper and lower two support plates 13 and 14, and the other blade plate 12 adjacent thereto is the support plates 13 and 14. It is being fixed to either of the support plates 13 and 14 alternately so that it may be fixed to the other of these. In one support plate 14, the support plate 14 and the blade plate 12 fixed to the support plate 14 are advanced and retracted along the arrangement direction X of the blade plate 12, that is, the direction in which the gas G flows in and out. Thus, a position adjustment mechanism 41 is provided that moves relative to the other support plate 13 and another adjacent blade 12 fixed to the support plate 13. Specifically, the position adjustment mechanism 41 includes a rack 42 provided on one support plate 14 along the arrangement direction X of the blades 12, a pinion 43 that meshes with the rack 42, and a drive that rotates the pinion 43. A stepping motor 44, and a control unit 45 that controls the stepping motor 44.

  Therefore, by driving the stepping motor 44 under the control of the control unit 45 and rotating the pinion 43, the one support plate 14 provided with the rack 42 and the blade 12 fixed to the support plate 14 are moved. The blade 12 can be moved along the arrangement direction X. Then, by moving the vane plate 12 fixed to one support plate 14 in this way along the arrangement direction X, the interval between the other adjacent vane plates 12 fixed to the other support plate 13 is increased. The width of the flow path 11 can be adjusted. For this reason, it is possible to adjust the balance between the droplet collection effect and the pressure loss brought about by narrowing the width of the flow path 11, and the moisture content of the gas G can be separated under optimum conditions.

  As mentioned above, although embodiment of this invention was explained in full detail with reference to drawings, the concrete structure is not restricted to this embodiment, The design change etc. of the range which does not deviate from the summary of this invention are included.

  In the moisture separator of each of the above embodiments, the blades are formed in a zigzag shape so that the flow path between the blades is formed in a zigzag shape. However, the present invention is not limited to this. is not. For example, the wing plate is alternately formed in a meandering shape, and the flow path may be formed in a meandering shape. In a flow path formed in a meandering shape including a zigzag shape. The same effect can be expected.

1 Gas cooler (cooler)
10, 30, 40 Moisture separator 11, 31 Channel 11A, 11B, 31A, 31B, 31C, 31D Curved portion 12, 32 Blade 18, 33 First projecting member (projecting member)
20, 35 First moisture collection pocket 21 Second moisture collection pocket 41 Position adjustment mechanism G Gas

Claims (5)

A moisture separator having a flow path through which a gas containing moisture is circulated and formed by a plurality of curved portions,
A first moisture collection pocket provided inside the curved portion of the flow path and opening from the curved portion toward the upstream side;
Moisture characterized in that the width of the flow path is narrower than the upstream side and the downstream side of the first moisture collection pocket at the position of the first moisture collection pocket Separator. The moisture separator according to claim 1.
A moisture separator, further comprising a second moisture collection pocket provided outside the curved portion of the flow path and opening from the curved portion toward the upstream side. The moisture separator according to claim 1 or claim 2,
A plate-like member formed in a serpentine shape, arranged with a plurality of intervals, and a blade plate having the flow path between each other,
A moisture separator, comprising: a protruding member fixed to the blade plate, protruding toward the upstream side of the flow path, and forming the first moisture collection pocket with the blade plate. The moisture separator according to claim 3,
A moisture separator comprising a position adjusting mechanism for relatively moving adjacent blade plates along a direction in which the blade plates are disposed. A moisture separator according to any one of claims 1 to 4;
A cooler comprising: a heat exchanger that exchanges heat with a gas to cool the gas and send the gas to the moisture separator.