JPS6240659Y2 - - Google Patents

Description

[Detailed Description of the Invention] The present invention relates to a moisture separation device suitable for use in a steam generator, a reheater, etc. to separate moisture and the like.

A conventional corrugated plate-shaped separator is shown in FIG. 1, which is a plan view thereof, and FIG.
It is constructed as shown in the figure, and consists of several dozen corrugated plates 1
01 is erected on the receiver 104, and the arrow 10
As shown in 2, an air stream containing droplets or solid particles (hereinafter referred to as moisture, etc.) is introduced, the moisture, etc. in the air stream is separated by centrifugal force, and only the gas is sent to the left in the direction of arrow 103. It is designed to flow out. A receiver 104 is provided below the corrugated plate 101 to support it. This receiver 1
04, an opening 10 is separated by a corrugated plate 101 and is used to discharge moisture, etc. that falls due to gravity downward.
5 are provided.

These are openings 105 with length L ₁ in the longitudinal direction.
and connecting portions 106 having a length L ₂ alternately. By the way, the connecting part 106
The liquid or solid particles separated in the channel 107 between the upper corrugated plates cannot be discharged. For this reason, a notch 108 is provided in the lower part of the corrugated plate 101 so that moisture, etc. in the flow path 107 can be discharged from the notch 108.

However, in the structure of such a device, the corrugated plate 1
01 from the entrance 102 to the exit 1 as shown by the arrow 109.
03 and a flow 110 flowing through the notch 108 (hereinafter referred to as a bypass flow). This bypass flow 11
The flow path resistance ζ exerted by the corrugated plate 101 with respect to 0
can be considered to be caused by the turning portions 111 of the flow path at each peak of the corrugated plate 101. In the example shown in FIG. For example, the resistance in the entire flow path becomes ζ≒7σ.

Therefore, a resistance of 7σ acts on the flow shown by arrow 109, whereas a resistance of only 2σ acts on the flow shown by arrow 110. Therefore, considering the flow velocity V ₁ on the outflow side of the flow indicated by arrow 109 and the flow velocity V ₂ on the outflow side of the flow indicated by arrow 110, the relationship of 7σ x V ₁ ² = 2σ x V ₂ ² is established according to the law of fluid mechanics. Because it holds true,
V ₂ is approximately 1.9 times V ₁ . For this the flow velocity V ₁
In the separator 101 designed based on the above, the lower bypass flow flows out at a speed _V2 as high as 1.9 times, resulting in a so-called carryover in which the moisture separated in the upper part is blown away in the lower part. That will happen. In addition, there is a problem in that the bypass flow that goes around below the opening 105 also causes the same carryover phenomenon as described above.

The present invention attempts to solve these problems by creating a structure that can avoid bypass flow, thereby preventing carryover and increasing the efficiency of separating moisture, etc. The purpose is to provide a moisture separation device.

For this reason, the moisture separator of the present invention is provided with a plurality of corrugated plates erected in a portion where airflow containing moisture passes through in order to separate moisture etc. in the airflow. The lower end of the corrugated sheet is provided with an opening for dropping moisture, etc. separated from the airflow upon contact with the corrugated sheet, and a lower tank connected to the opening. In order to prevent a bypass flow of the airflow going around downward, a guide passage for the moisture, etc. is formed by a partition wall extending from the lower end of the corrugated plate through the opening into the lower tank. There is.

Hereinafter, a moisture separator as an embodiment of the present invention will be explained with reference to the drawings. FIG. 3 is a longitudinal sectional view thereof, FIG. 4 is a cross sectional view of the - part in FIG. Each figure is a cross-sectional view showing a modified example corresponding to FIG. 4.

As shown in FIG. 3, an airflow passing portion 101a exists between an inflow side 102a and an outflow side 103a.
Inside, in the same manner as in FIGS. 1 and 2, a large number of corrugated plates 101 extending along the flow direction of the airflow are installed in order to separate moisture and the like in the airflow.

A receiver 104 for supporting the corrugated sheets 101 is provided below these corrugated sheets 101.
A plurality of openings 105 are provided at the bottom of the receiver 104 for discharging moisture and the like separated from the airflow as the airflow comes into contact with the corrugated plate 101.

Further, a notch 108 is formed in the lower part of the corrugated plate 101, so that moisture etc. that have fallen into the connecting portion 106, which is the bottom of the receiver 104 other than the opening 105, can be discharged.

A lower tank 202 is connected to the opening 105, and inside the lower tank 202, a plurality of partition walls 203 are provided that extend downward from the lower end of the corrugated sheet 101 through the opening 105.

This partition wall 203 is composed of a thin plate having a cross section as shown in FIG.
01.

A bottom plate 2 is provided at the bottom of the lower tank 202.
A barb-shaped outlet protrusion 20 extending from one end of 07
8 is formed so that the separated liquid staying in the lower tank 202 passes between the bottom plate 207 and the lower end of the guide passage 201 and then overflows from the outlet protrusion 208 as shown by the arrow 205. It's getting old. Note that the height h of the outlet protrusion 208 is equal to the gap 2 between the lower end of the guide passage 201 and the bottom plate 207.
It is necessary that the size is equal to or larger than the size a of 09.

Since the moisture separator of the present invention is constructed as described above, the inflow side 102 is
The airflow flowing into the airflow passage portion 101a from a is
When the corrugated sheet 101 comes into contact with the corrugated sheet 101, moisture and the like in the airflow adheres to the corrugated sheet 101. This moisture flows down along the corrugated plate 101 and stays in the lower part of the lower tank 202 through the opening 105 and the guide passage 201. Moisture and the like separated in the air flow passage portion 107 above the joint portion fall into the joint portion 106 and then guided to the opening portion 105 through the notch portion 108.

The separated liquid that has flowed into the lower tank 202 stays in the lower part of the bottom plate 207 and the guide passage 201.
Since the height a of the gap 209 between the lower end and the height h of the outlet protrusion 208 is equal to or larger, the separation continues until the gap 209 is filled with the separated liquid discharged. This is because the liquid is not drained. Therefore, the airflow flowing in from the inlet side 102 does not flow out through the outlet protrusion 208 of the lower tank 202.

Further, the bypass flow that goes around below the lower end of the corrugated plate 101 is blocked by the partition wall 203, and as a result, the bypass flow as in the conventional case is reduced and the liquid flowing down along the corrugated plate 101 is repelled. This makes it possible to avoid carryover, and as a result, moisture and the like in the airflow can be efficiently separated.

Next, a modification of the moisture separator of the present invention will be described. Figures 5 to 8 all show modifications of the shape of the partition wall 203 described above.

That is, in the modification shown in FIG.
3a is constructed by combining thin plates so as to have a grid-like cross section, thereby forming a guide passage 201a with a rectangular cross section, which has the same function as the partition wall 203 and the guide passage 201 shown in FIG. It is becoming more and more common to have one.

Further, in the modification shown in FIG. 6, the partition wall 203b
is configured to have a honeycomb-shaped cross section, and a guide passage 201b with a hexagonal cross section is formed, so that it also has the same function as the partition wall 203 and the guide passage 201 shown in FIG. ing.

Furthermore, in the modification shown in FIG.
c is constituted by a collection of pipes, and a cylindrical guide passage 201c is formed to have the same function as the partition wall 203 and the guide passage 201 shown in FIG.

In the modification shown in FIG. 8, the partition wall 203
d is constructed like a cardboard made by joining parallel thin plates with corrugated plates, and the guide passage 20 has a triangular cross section.
1d is formed to have the same function as the partition wall 203 and the guide passage 201 shown in FIG.

As described above, in each modification, the partition walls 203a,
203b, 203c, 203d, the corrugated plate 10
The bypass flow that goes around below the lower end of the corrugated plate 101 is blocked in its path, thereby reducing the conventional bypass flow and avoiding carryover in which the liquid flowing down along the corrugated plate 101 is splashed. As a result, it becomes possible to efficiently separate moisture, etc. in the airflow, and the same effects as in the above-mentioned embodiments can be obtained.

As described in detail above, according to the moisture separator of the present invention, a plurality of corrugated plates erected in the air passage containing moisture etc. are installed in order to separate the moisture etc. in the airflow. In addition, an opening is provided below the corrugated plate to allow moisture, etc. separated from the airflow to fall when the airflow comes into contact with the corrugated plate, and a lower tank is connected to the opening. In order to prevent a bypass flow of the airflow going around below the lower end of the corrugated plate, a partition wall extending from the lower end of the corrugated plate through the opening into the lower tank creates a guide passage for the moisture, etc. This simple structure has the advantage of efficiently separating and removing moisture from a mixed gas of gas and moisture.

[Brief explanation of the drawing]

Figures 1 and 2 show a conventional moisture separator; Figure 1 is a plan view thereof, Figure 2 is a sectional view taken along the - arrow, and Figures 3 to 8 are examples of embodiments of the present invention. Fig. 3 is a vertical sectional view thereof, Fig. 4 is a cross sectional view of the minus part in Fig. 3, and Figs. 5 to 8 all show modified examples thereof. FIG. 5 is a cross-sectional view corresponding to FIG. 4; 101...corrugated plate, 101a...airflow passage part,
102a...Inflow side, 103a...Outflow side, 10
4...Receiver, 105...Opening, 106...Connection, 107...Airflow passing portion above the connection,
108... Notch, 201, 201a, 20
1b, 201c, 201d...guidance passage, 202
...lower tank, 203, 203a, 203b,
203c, 203d... bulkhead, 207... bottom plate,
208...Exit protrusion, 209...Gap.

Claims (1)

[Scope of utility model registration request] A plurality of corrugated plates are installed in the area where the airflow containing moisture passes through to separate the moisture in the airflow, and below the corrugated plates, the airflow comes into contact with the corrugated plates. In order to prevent the bypass flow of the air flow from going around below the lower end of the corrugated plate, it is provided with an opening for dropping moisture etc. separated from the air flow and a lower tank connected to the opening. . A moisture separation device, characterized in that a guide passage for the moisture, etc. is formed by a partition wall extending from the lower end of the corrugated plate through the opening into the lower tank.