JP2012016678A - Plate column - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a plate column which assures constant driving to obtain gas absorption as has been designed even when the driving condition is changed and the amount of gas supply is increased.SOLUTION: The plate column includes a plate 3, a liquid supply section 4 and a gas supply section, and a liquid and a gas are made to be contact to each other on the plate 3. The liquid supply section 4 supplies the liquid to one side of the plate 3, and the plate 3 is equipped with a discharge section 6 for discharging the liquid to the other side. On the plate 3, a stopping 7 is provided on one side from the discharge section 6, and on one side from the stopping 7, a guide section 10 for guiding the gas from the gas supply section on the plate 3. A flow passage 9 for the gas communicating to the guide section 10 is formed on the plate 3, and a porous plate 8 for discharging the gas upward from the flow passage 9 is provided. The porous plate 8 is provided with an extending section 13 on the stopping side, extending to the side of the stopping 7 from the guide section 10A positioned most closely to the side of the stopping 7. On the extending section 13 on the stopping side, a gas blocking section 14 is provided to block the gas discharging out of the side closer to the stopping 7 from the position of the extending section 13 on the stopping side.

Description

  The present invention relates to a plate tower for making gas-liquid contact.

Conventionally, a tower column having a plurality of shelves is known as an absorption tower, a distillation tower, a rectification tower, and the like. In such a plate tower, in the absorption tower, for example, exhaust gas is absorbed in the liquid, components in the exhaust gas are recovered, and effective use (reuse) is performed.
In addition, such a plate tower is also known in which a porous film (porous plate) having a large number of pores is used as a shelf plate (see, for example, Patent Document 1 and Patent Document 2).

  Furthermore, there is also known a plate tower in which a porous plate is arranged on the shelf plate and gas taken from below the shelf plate is allowed to flow out above the porous plate through the pores of the porous plate. In this shelf tower, the gas introduced from the lower side of the shelf plate is taken into the channel formed between the shelf plate and the perforated plate through the cylindrical portion formed on the shelf plate and the bubble bell covering the shelf portion. Further, gas is allowed to flow out from the flow path above the perforated plate.

  Further, in this shelf tower, the liquid is supplied to one side of the shelf board, the weir formed on the other side of the shelf board is overflowed, and the liquid is allowed to flow downward from the outflow portion of the liquid. . Thereby, the liquid supplied to one side of the shelf plate flows on the perforated plate until it overflows the weir. Therefore, the gas flowing out from the pores of the perforated plate flows into the liquid flowing on the perforated plate and passes therethrough so as to come into gas-liquid contact.

Japanese Patent Publication No. 5-5521 JP 2002-102601 A

  By the way, in the shelf tower provided with a porous plate as described above, in order to ensure a sufficiently wide flow path between the shelf plate and the porous plate, a cylindrical portion formed on the shelf plate as a porous plate and The size is extended to the outside of the bubble bell. Therefore, this perforated plate also extends on the dam side, particularly from the bubble bell body located closest to the dam side among the bubble bell bodies, further to the dam side to form a dam side extending portion.

  However, since such a dam side extension portion is formed, conventionally, a part of the gas flowing out from the dam side extension portion becomes a bubble and is located on the most dam side among the bubble bell bodies. Due to this, the pressure loss of the gas passing through the liquid flowing on the shelf plate is reduced and the gas-liquid contact time is shortened. Absorbability may be reduced.

The inventor investigated the cause of such a phenomenon, and found that the above phenomenon occurred mainly when the operating conditions were changed and the gas supply amount increased from the set conditions.
The present invention has been made in view of the above circumstances, and its object is to reduce the gas absorbency into the liquid even when the operating conditions are changed and the gas supply amount is increased. An object of the present invention is to provide a plate tower that can be stably operated so as to obtain a gas absorption property as designed.

The shelf tower of the present invention includes a shelf plate, a liquid supply unit that supplies liquid onto the shelf plate, and a gas supply unit that vents gas from the bottom surface side to the top surface side of the shelf plate, A tray tower for contacting the liquid and the gas on a shelf board,
The liquid supply unit is configured to supply liquid to one side of the shelf board,
The shelf plate is provided with an outflow portion that causes the liquid on the shelf plate to flow downward on the other side,
On the shelf, a weir is provided on one side of the shelf from the outflow portion,
On one side of the shelf board from the weir of the shelf board, a guide unit for guiding the gas vented from the gas supply unit onto the shelf board is provided,
On the shelf plate, a perforated plate is provided that forms a gas flow path communicating with the guide portion between the shelf plate and allows gas to flow out from the flow path above the shelf plate,
The perforated plate is provided with a weir-side extension portion extending from the guide portion located closest to the weir side among the guide portions to the weir side,
The dam side extending portion is provided with a gas blocking portion that blocks the gas from flowing out from the dam side to the upper side of the shelf board from the position.

  According to this shelf tower, the weir side extension part is located between the guide part located closest to the weir side of the guide part and the side end part on the weir side of the weir side extension part from the position. Since a gas blocking part is provided to block the gas from flowing out above the shelf from the side, there is no gas flowing out from the weir side from this gas blocking part, so the most of the guide part on the weir side Air bubbles are prevented from staying between the guide portion and the weir. Therefore, the air bubbles stay in this way, the pressure loss of the gas passing through the liquid flowing on the shelf plate is reduced, and the gas-liquid contact time is shortened, so that the gas absorption into the liquid may be reduced. Can be suppressed.

Further, in the shelf tower, the gas blocking portion is provided so as to block the gas from flowing out above the shelf plate from the weir side from the guide portion located closest to the weir side among the guide portions. It is preferred that
If it does in this way, it will prevent more reliably that a bubble stays between the guide part located in the dam side most among a guide part, and a dam.

Another shelf tower of the present invention includes a shelf plate, a liquid supply unit that supplies a liquid onto the shelf plate, and a gas supply unit that vents gas from the bottom surface side to the top surface side of the shelf plate. , A shelf tower for contacting the liquid and the gas on the shelf board,
The liquid supply unit is configured to supply liquid to one side of the shelf board,
The shelf plate is provided with an outflow portion that causes the liquid on the shelf plate to flow downward on the other side,
On the shelf, a weir is provided on one side of the shelf from the outflow portion,
On one side of the shelf board from the weir of the shelf board, a guide unit for guiding the gas vented from the gas supply unit onto the shelf board is provided,
On the shelf plate, a perforated plate is provided that forms a gas flow path communicating with the guide portion between the shelf plate and allows gas to flow out from the flow path above the shelf plate,
The perforated plate is arranged on the shelf plate without extending the side end portion on the dam side from the guide portion located closest to the dam side among the guide portions to the dam side. It is a feature.

  According to this shelf tower, the perforated plate is arranged on the shelf plate without the side end portion on the weir side extending from the guide portion located closest to the weir side among the guide portions to the weir side. Therefore, no gas flows out from the weir side from the guide portion located closest to the weir side among the guide portions, so that bubbles are formed between the guide portion located closest to the weir side and the weir among the guide portions. Retention is reliably prevented. Therefore, the air bubbles stay in this way, the pressure loss of the gas passing through the liquid flowing on the shelf plate is reduced, and the gas-liquid contact time is shortened, so that the gas absorption into the liquid may be reduced. Can be suppressed.

In the shelf tower, the guide portion includes an opening formed in the shelf plate, a cylinder portion that communicates with the opening and extends on the shelf plate, passes through the porous plate, and is located above the cylinder portion. A covered cylindrical bubble bell that is arranged and covers the upper opening of the cylindrical portion without closing, and communicates with the upper opening and forms a guide path that communicates with the flow path. Also good.
Since the guide portion is configured to have such an opening, a cylindrical portion, and a bubble bell, the gas supplied by being supplied from the lower side of the shelf plate by the gas supply portion is passed between the shelf plate and the porous plate. It is possible to guide well to the flow path.

  According to the tray tower of the present invention, it is possible to prevent bubbles from staying between the guide portion located closest to the dam among the guide portions and the weir, and to reduce the gas absorbability into the liquid. Since it is suppressed, for example, even when the operating conditions are changed and the gas supply amount is increased, the gas absorbency as designed can be obtained without the possibility of reducing the gas absorbability into the liquid. Therefore, it is possible to operate stably as designed without being affected by the operating conditions.

It is a schematic diagram which shows the internal schematic structure of 1st Embodiment of the shelf tower which concerns on this invention. It is a schematic diagram which shows the principal part side cross section of 1st Embodiment of the shelf tower which concerns on this invention. It is a schematic diagram which shows the principal part side cross section of the conventional plate tower. It is a schematic diagram which shows the principal part side cross section of the conventional plate tower. (A) is a schematic diagram which shows the principal part side cross section of 2nd Embodiment of the shelf tower which concerns on this invention, (b) is a perspective view of a perforated plate. It is a schematic diagram which shows the principal part side cross section of 3rd Embodiment of the shelf tower which concerns on this invention.

Hereinafter, the tray tower of the present invention will be described in detail.
FIG. 1 is a diagram for explaining a first embodiment of a plate tower according to the present invention, and is a schematic diagram showing a schematic configuration inside the plate tower. In each drawing used for the following description, the scale of each member is appropriately changed to make each member a recognizable size.
In FIG. 1, reference numeral 1 denotes a tray tower. The tray tower 1 includes a cylindrical tower body 2 having a bottom plate 2 a and a cover plate 2 b and a plurality of shelf boards (shelf) provided in the tower body 2. Stage) 3.

  Above the uppermost shelf 3a, a liquid supply pipe (liquid supply unit) 4 for supplying a liquid onto the shelf 3a is disposed, and below the lowermost shelf 3c, the shelf 3c. A gas supply pipe (gas supply part) 5 for allowing gas (gas) to flow from the bottom surface side to the top surface side is disposed. Further, the cover plate 2b of the tower body 2 is provided with an exhaust pipe 2c for discharging gas.

  The liquid supply pipe 4 penetrates the side wall of the tower main body 2 and its tip side is positioned in the tower main body 2. The liquid is supplied by being pumped from a liquid supply source (not shown) by a pump or the like. ing. In the present embodiment, a plurality (two) of liquid supply pipes 4 are provided, and the liquid supply section of the present invention is formed by the plurality of liquid supply pipes 4.

  Further, the gas supply pipe 5 also penetrates the side wall of the tower body 2 and its tip side is positioned in the tower body 2 so that gas is pumped and supplied from a gas supply source (not shown). Yes. For example, water is used as the liquid supplied from the liquid supply pipe 4 onto the shelf board 3. Moreover, as a gas (gas) vented into the tower body 2 from the gas supply pipe 5, for example, nitrogen oxide (NOx) is used.

  Under such a configuration, the shelf column 1 makes the liquid (water) supplied from the liquid supply pipe 4 and the gas (NOx) supplied from the gas supply pipe 5 come into contact with each other on the shelf board 3, For example, nitric acid is produced by absorbing gas.

  The liquid supply pipe 4 has a liquid supply port (not shown) at the tip of one side of the shelf 3a (the left side in FIG. 1) so that the liquid is supplied to one side of the uppermost shelf 3a. ). In addition, the shelf 3a is provided with an outflow portion 6 on the other side (the right side in FIG. 1) for allowing the liquid on the shelf 3a to flow downward. The outflow portion 6 is composed of a plurality of outflow pipes 6a provided in through holes (not shown) formed in the shelf plate 3a, and the shelf plate 3b is placed on the shelf step 3b below the shelf plate 3a. The liquid which flows out from 3a is supplied.

  Therefore, the outflow part 6 composed of a plurality of outflow pipes 6a functions as the outflow part 6 for allowing the liquid on the shelf board 3 to flow downward in the shelf board 3 provided with the outflow pipe 6a. The lower shelf 3 functions as a liquid supply pipe (liquid supply unit) 4 for supplying liquid.

  In addition, since the outflow part 6 that functions as the liquid supply pipe 4 is arranged on the right side in FIG. 1 with respect to the shelf 3b one below the uppermost shelf 3a in this way, this shelf In 3b, the side on which the liquid supply pipe 4 comprising the outflow portion 6 is disposed is one side, and the opposite side (left side in FIG. 1) is the other side. Accordingly, in this shelf plate 3b, on the side opposite to the side where the liquid supply pipe 4 comprising the outflow portion 6 is disposed, the outflow portion 6 having the same configuration as the outflow portion 6 in the shelf plate 3a, that is, a plurality of outflow pipes. The outflow part 6 which consists of 6a is provided.

  The outflow portion 6 in the shelf plate 3b also functions as a liquid supply pipe (liquid supply portion) 4 with respect to the shelf plate 3c below it, and the same configuration is repeated thereafter. However, since the outflow part 6 provided in the lowest shelf 3 has no shelf 3 below it and is a bottom plate 2a, it has only a function of allowing the liquid to flow out onto the bottom plate 2a. The liquid that has flowed out onto the bottom plate 2a is discharged out of the tray column 1 from a discharge pipe (not shown). Further, in FIG. 1, the number of steps of the shelf board 3 is omitted and only three steps are described, but actually, there may be more or less steps.

  On each shelf 3, a plate-like weir 7 is disposed on the side where the outflow portion 6 is formed. The weir 7 is disposed slightly on the liquid supply pipe 4 side, that is, on one side of the shelf board 3 from the position where the outflow portion 6 is formed, and is formed at a predetermined height designed in advance. . This weir 7 blocks the amount of the liquid supplied from the liquid supply pipe 4 arranged on one side of the shelf board 3 according to the height, and overflows the excess amount.

  As a result, the liquid overflowing the weir 7 flows out from the outflow portion 6 onto the lower shelf 3. Further, the liquid supplied to one side of the shelf 3 by the liquid supply pipe 4 flows on the shelf 3 until it overflows the weir 7 arranged on the other side of the shelf 3. ing.

  A porous plate 8 is placed on the shelf plate 3. As shown in FIG. 2, which shows the main part of the plate tower 1, the porous plate 8 comprises a cylindrical side wall portion 8a having a low height and a porous plate body 8b covering the upper opening of the side wall portion 8a. Thus, a large number of pores 8c are formed only in the porous plate body 8b without forming holes in the side wall 8a. The perforated plate body 8b is formed with an opening (not shown) through which a cylindrical portion of a guide portion described later is inserted. Under such a configuration, the porous plate 8 forms a gas (gas) flow path 9 between the porous plate body 8 b and the shelf plate 3. The perforated plate body 8b is formed of, for example, a punching metal having pores 8c having an inner diameter of about 2 mm to 4 mm.

  Further, the shelf plate 3 guides the gas vented from the gas supply pipe (gas supply section) 5 to the liquid supply pipe 4 side (one side of the shelf board 3) from the weir 7 onto the shelf board 3. For this purpose, a plurality of guide portions 10 are provided. The guide portions 10 include an opening (not shown) formed in the shelf plate 3, a cylinder portion 11 that communicates with the opening and extends on the shelf plate 3, and a covered cylinder disposed on the upper side of the cylinder portion 11. And a bubble-shaped body 12 having a shape.

  The cylinder part 11 is long and thin, with the direction perpendicular to the straight line connecting the side (one side) where the liquid supply pipe 4 is arranged and the side (the other side) where the outflow part 6 is provided as the long side. It has a rectangular (rectangular) cylindrical shape, and its upper side passes through an opening (not shown) of the porous plate body 8b and is positioned on the opening (not shown).

  The bubble bell 12 has a rectangular (rectangular) cylindrical side wall portion 12a that is slightly larger than the cylindrical portion 11, and a lid portion 12b that covers the upper opening of the side wall portion 12a. The side wall portion 12a is disposed on the cylinder portion 11 with a predetermined width between the side wall portion 12a and the cylinder portion 11. Further, the bubble bell 12 is placed on the porous plate main body 8b of the porous plate 8, and is fixed by welding, screwing, or the like, thereby fixing the relative position with respect to the cylindrical portion 11.

  And the guide part 10 guides the gas supplied to the bottom face side of the shelf board 3 from the gas supply pipe (gas supply part) 5 on the shelf board 3 via the cylinder part 11 by such a structure, Furthermore, it is made to flow in into the flow path 9 between the shelf board 3 and the porous board main body 8b through the clearance gap between the cylinder part 11 and the bubble bell body 12. FIG. That is, a guide path (not shown) communicating with the flow path 9 is formed in the cylinder portion 11 and by a gap between the cylinder portion 11 and the bubble bell 12. The gas that has flowed into the flow path 9 in this way passes through the pores 8 c of the porous plate body 8 and flows out onto the porous plate 8.

  Here, the perforated plate 8 sufficiently covers the regions where the plurality of guide portions 10 are formed, and ensures a sufficiently wide flow path 9 between the shelf plate 3 and the perforated plate 8. Therefore, it is formed in a size sufficiently wider than the region. Therefore, on the dam 7 side, the dam side extending portion 13 is formed on the perforated plate 8 so as to extend from the guide portion 10A located closest to the dam 7 to the dam 7 side.

  Further, as described above, the liquid supplied by the liquid supply pipe 4 flows on the shelf plate 3 until it overflows the weir 7. However, since the flow path 9 is formed between the shelf plate 3 and the porous plate body 8b, and the gas flows in the flow path 9, the liquid supplied from the liquid supply pipe 4 is The pressure hardly flows into the flow path 9 and flows on the porous plate 8 (porous plate body 8b) and on the bubble bell 12.

  Therefore, the gas flowing out on the porous plate body 8b through the flow path 9 flows into the liquid flowing on the porous plate body 8b or the bubble bell 12 and passes therethrough to come into gas-liquid contact. Yes. That is, the gas that has flowed out onto the perforated plate main body 8b passes through the liquid as bubbles B, and a part of the gas dissolves in the liquid, thereby being absorbed in the liquid. The remaining part passes through the liquid and rises.

  Here, the bubble B rises almost directly above the liquid without being substantially affected by the flow of the liquid. Therefore, when the gas flow rate is constant, the higher the thickness (thickness) of the liquid layer of the liquid flowing on the porous plate 8 (porous plate body 8b), the longer the bubble B is in contact with the liquid. It becomes longer and the ratio absorbed in the liquid becomes higher. In FIG. 2, the widths of the bubble bell bodies 12 and the cylindrical portion 11 are widely shown for easy viewing. However, in reality, the interval between the adjacent bubble bell bodies 12, 12 is larger. Wide enough than

  The height (thickness) of the liquid layer of the liquid flowing on the porous plate 8 (porous plate body 8b) is basically determined by the height of the weir 7. That is, the height (thickness) H1 of the liquid layer on the side of the designed weir 7 is higher than the height of the weir 7 by a height that overflows the weir 7 (thickness). On the other hand, the apparent height H2 of the liquid layer on the perforated plate main body 8b contains a large amount of bubbles B. Therefore, the design corresponds to the height corresponding to the height of the weir 7 as shown in FIG. The thickness (thickness) is higher (thicker) than H1.

  This shows the conventional structure because the flow rate of the gas supplied from the gas supply pipe 5 is as set and the flow rate is relatively slow as set in normal operation by design. This is because, as shown in FIG. 3, the bubbles B hardly flow out from the weir side extending portion 13. That is, when the flow rate of the gas is as set, the gas guided from the guide portion 10A located closest to the weir 7 to the flow path 9 in the guide portion 10 is transferred to the end of the weir-side extension portion 13. This is because the gas does not flow to the portion side (weir 7 side) but rises before it and flows out from the pores 8c of the porous plate body 8b.

In this way, since there are almost no bubbles B in the liquid on the weir 7 side, the liquid layer on the weir 7 side is a true liquid layer made only of the liquid, and therefore the weir 7 shown in FIGS. The height (thickness) H1 of the liquid layer corresponding to the height of is the height of the true liquid layer.
On the other hand, the height H2 of the liquid layer at a position corresponding to the space between the bubble bodies 12 and 12 is as shown in FIGS. 2 and 3 because many bubbles B exist in the liquid. Further, the volume of the bubble B is higher than the height H1 of the true liquid layer. This is because the liquid pressure (water pressure) is constant throughout the liquid layer on the liquid supply pipe 4 side from the weir 7, and this liquid pressure is determined by the liquid pressure of the liquid layer on the weir 7 side. In other words, the height H2 of the liquid layer at a position corresponding to the space between the bubble bodies 12 and 12 determines the substantial liquid pressure, and the height of the true liquid layer made of only the liquid is higher than that of the bubble B. Since the volume is added, it is apparently higher than the height H1 of the true liquid layer.

  However, even in the region where the height of the liquid layer is H2, the true liquid layer is H1, and the liquid pressure is also a pressure corresponding to the true liquid layer H1, so the pressure of the gas passing therethrough The loss is as designed, and the contact time with the liquid is also the time set by the height of the weir 7. Therefore, by having the contact efficiency as designed, the gas absorbency into the liquid is also as set.

  However, when the operating conditions are changed due to some external factor or the like and the gas supply amount increases, conventionally, a part of the gas flowing out from the weir-side extending portion 13 becomes bubbles B as shown in FIG. The bell 12 flows between the bubble bell 12A located closest to the weir 7 and the weir 7, and thus temporarily stays in the liquid in this region. This is because if the flow rate of the gas supplied from the gas supply pipe 5 is as set, the gas (bubble B) hardly flows out from the weir-side extending portion 13 as described above. Since the flow rate of the gas supplied from the supply pipe 5 has increased from the setting, the gas flow rate also increases, flows to the end portion side (weir 7 side) of the weir side extension portion 13, and gas ( This is because the bubbles B) have flowed out.

  Even if the bubble B stays between the bubble bell 12A and the weir 7 in this way, the height of the liquid layer in this region is determined by the height of the weir 7 as described above. H1 shown in FIG. However, unlike the case shown in FIGS. 2 and 3, in the case shown in FIG. 4, the liquid layer in the region between the bubble bell 12 </ b> A and the weir 7 contains many bubbles B. The height of the true liquid layer consisting only of the liquid is much lower than H1. That is, in the state shown in FIG. 4, the height of the liquid layer on the weir 7 side is the height of the apparent liquid layer containing many bubbles B. Therefore, the hydraulic pressure is also much smaller than the designed hydraulic pressure shown in FIG.

  Then, as described above, the liquid pressure is constant throughout the liquid layer, and this liquid pressure is determined in accordance with the height of the true liquid layer on the weir 7 side. Therefore, in the case shown in FIG. The liquid pressure in the liquid layer at a position corresponding to the space between the bodies 12 and 12 is significantly lower than the liquid pressure in the region between the bubble body 12A and the weir 7 shown in FIG. That is, the height of the liquid layer at a position corresponding to the space between the bubble bodies 12 and 12 is much lower than the designed height H2 shown in FIGS.

  Therefore, conventionally, when the operating conditions are changed and the gas supply amount is increased, the height of the liquid layer at a position corresponding to the space between the bubble bell bodies 12 and 12 is much lower than the set height. The liquid pressure of the liquid layer at the position is also much lower than the set liquid pressure. Then, the pressure loss of the gas passing through the liquid flowing on the shelf 3 is reduced, and the gas-liquid contact time is shortened, so that the gas absorbability into the liquid may be reduced.

  Therefore, in the present embodiment, as shown in FIG. 2, the weir-side extension portion 13 includes a bubble bell 12 </ b> A (guide 10 </ b> A) positioned closest to the weir 7 among the bubble bells 12 (guide 10). A gas blocking part (gas blocking part) 14 is provided between the weir side extending part 13 and the side end part (side wall part 8a) on the weir 7 side, which blocks gas from flowing out from the position of the weir 7 side. ing.

  That is, in the present embodiment, the pore 8c of the porous plate body 8b is blocked at a part of the weir side extending portion 13 on the side of the weir 7, thereby blocking outflow of gas from the closed pore 8c. I am doing so. Further, the bubble bell 12 (guide portion 10) is extended to the weir side so as to block gas from flowing out from the weir 7 side from the bubble bell body 12A (guide portion 10A) located closest to the weir 7 side. It is preferable to provide a gas blocking part (gas blocking part) 14 over the entire area of the part 13. (In FIG. 2, the state which provided the gas interruption | blocking part 14 in the whole region of the dam side extension part 13 is shown.)

  Specifically, in the present embodiment, the pores 8c are closed by covering the pores 8c with, for example, a plate or putting a filler in the pores 8c. Therefore, the gas blocking part 14 of this embodiment is formed by these plates and fillers. Such a gas blocking part 14 may be provided only on a part of the weir side extending part 13 on the side of the weir 7 as described above, but it is located closest to the weir 7 side of the bubble bell 12 (guide part 10). It is preferable to provide in the whole area which becomes the weir 7 side from 12 A (guide part 10A) to perform.

  Since the gas blocking unit 14 is provided in this way, in the shelf tower 1 of the present embodiment, for example, even if the operating conditions are changed and the gas supply amount increases, Gas does not flow out from the weir 7 side from the gas blocking part 14. Therefore, the bubble B is prevented from staying in the liquid between the bubble bell 12A (guide 10A) located closest to the weir 7 and the weir 7 among the bubble bells 12 (guide 10), or It can be surely prevented.

Therefore, the bubbles B stay in this way, the pressure loss of the gas passing through the liquid flowing on the shelf 3 is reduced, and the gas-liquid contact time is shortened, so that the gas absorbability into the liquid is reduced. The possibility of a decrease can be suppressed.
Therefore, according to the plate tower 1 of this embodiment, even when the operating conditions are changed and the gas supply amount is increased, the gas absorption as designed is possible without reducing the gas absorption into the liquid. Sex can be obtained. Therefore, it is possible to operate stably as designed without being affected by the operating conditions.

Next, a second embodiment of the tray tower of the present invention will be described.
FIG. 5 (a) is a diagram showing a second embodiment of the shelf tower of the present invention, and is a diagram showing the main part of the weir side extension 13. The plate tower of the second embodiment is different from the plate tower of the first embodiment shown in FIG. That is, the gas blocking unit 14 shown in FIG. 2 is configured by a plate covering the pores 8c and a filling material filled in the pores 8c, whereas the gas blocking unit (gas blocking unit) of the present embodiment. ) 15 is formed by a plate-like or columnar member provided on the bottom surface side of the porous plate main body 8b as shown in FIG. 5 (b).

  As shown by the solid line in FIG. 5 (a), the gas blocking portion 15 made of a plate-like or columnar member has a bubble bell 12A (guide portion 10A) in the weir-side extension portion 13 and a side on the weir 7 side. It arrange | positions between an edge part (side wall part 8a). Further, as shown by a two-dot chain line in FIG. 5A, the bubble bell 12A (guide portion 10A) is disposed at the same position as the side wall 12a on the weir 7 side of the bubble bell 12A. Is preferred.

  As described above, since the gas blocking portion 15 is disposed between the bubble bell 12A (guide portion 10A) and the side end portion on the weir 7 side, even in the tray tower of the present embodiment, for example, the operation condition is changed. Thus, when the gas supply amount increases, the gas does not flow out from the gas blocking part 15 to the weir 7 side in the weir side extending part 13. Therefore, it is possible to prevent the bubbles B from staying in the liquid between the bubble bell 12A (guide 10A) located closest to the weir 7 and the weir 7 in the bubble bell 12 (guide 10). Can do.

Therefore, the bubbles B stay in this way, the pressure loss of the gas passing through the liquid flowing on the shelf 3 is reduced, and the gas-liquid contact time is shortened, so that the gas absorbability into the liquid is reduced. The possibility of a decrease can be suppressed.
Therefore, according to the tray tower of the present embodiment, even when the operating conditions are changed and the gas supply amount is increased, the gas absorptivity as designed without reducing the gas absorptivity into the liquid. Can be obtained. Therefore, it is possible to operate stably as designed without being affected by the operating conditions.

Next, a third embodiment of the tray tower of the present invention will be described.
FIG. 6 is a diagram showing a third embodiment of the shelf tower of the present invention and is a diagram showing the main part of the shelf tower. The plate tower of the third embodiment is different from the plate tower of the first embodiment shown in FIG. 2 in the configuration of the perforated plate. That is, the perforated plate 8 shown in FIG. 2 has, on the weir 7 side, a weir side extending portion 13 that further extends to the weir 7 side from the guide portion 10A located closest to the weir 7 side among the guide portions 10. On the other hand, the perforated plate 16 of the present embodiment is not formed with the weir-side extension as shown in FIG.

  Therefore, in the porous plate 16 of this embodiment, the side wall part (side end part) 16a on the weir 7 side has the bubble bell body 12A (guide) which is located closest to the weir 7 side among the bubble bell bodies 12 (guide part 10). The side wall portion 12a on the weir 7 side of the portion 10A) is disposed at the same position, and the space between them is sealed by welding or the like as necessary. That is, the side wall portion 16a of the porous plate 16 arranged at the same position as the side wall portion 12a on the weir 7 side functions in the same manner as the gas blocking portion 15 indicated by a two-dot chain line in FIG. Regardless of the presence or absence of the side extending portion 13, the gas is prevented from flowing out from the side wall portion 16a from the weir 7 side.

  Therefore, in the tray tower of this embodiment, for example, when the operating condition is changed and the gas supply amount is increased, the side wall portion (side end portion) 16a on the weir side of the porous plate 16 is Since the bubble 12a (guide 10A) located closest to the weir 7 side of the body 12 (guide 10) does not extend to the weir 7 side, the bubble 7 side from this bubble 12A (guide 10A) It is possible to reliably prevent gas from flowing out of the tank.

Therefore, since it is possible to reliably prevent the bubbles B from staying between the bubble bell 12A (guide portion 10A) and the weir 7, the liquid flowing on the shelf 3 due to the bubbles B staying in the liquid The pressure loss of the gas passing through the gas can be reduced, and the gas-liquid contact time can be shortened, thereby suppressing the possibility that the gas absorbability into the liquid may be reduced.
Therefore, according to the tray tower of the present embodiment, even when the operating conditions are changed and the gas supply amount is increased, the gas absorptivity as designed without reducing the gas absorptivity into the liquid. Can be obtained. Therefore, it is possible to operate stably as designed without being affected by the operating conditions.

The present invention is not limited to the above-described embodiment, and various modifications can be made without departing from the gist of the present invention.
For example, the number of shelves is arbitrary as described above, and the number of guide portions arranged on the same shelf is also arbitrary.
As for the structure of the guide unit, the gas (gas) vented to the gas supply unit (gas supply pipe 5) can be guided onto the shelf plate, and the guided gas (gas) is guided to the shelf plate and the porous plate. If it is the structure which can guide to the flow path formed between, it will not be limited to the structure of the guide part 10 of the said embodiment.

DESCRIPTION OF SYMBOLS 1 ... Shelf tower, 2 ... Tower main body, 3 (3a, 3b, 3c) ... Shelf board, 4 ... Liquid supply pipe (liquid supply part), 5 ... Gas supply pipe (gas supply part), 6 ... Outflow part, DESCRIPTION OF SYMBOLS 7 ... Weir, 8 ... Perforated plate, 8a ... Side wall part, 8b ... Perforated plate main body, 8c ... Fine pore, 9 ... Channel, 10, 10A ... Guide part, 11 ... Cylindrical part, 12 ... Bubble bell, 13 ... Weir-side extension part, 14 ... gas blocking part (gas blocking part), 15 ... gas blocking part (gas blocking part), 16 ... perforated plate, 16a ... side wall, 16b ... perforated plate body, 16c ... pore, B ... bubbles

Claims (4)

A shelf plate, a liquid supply unit that supplies liquid onto the shelf plate, and a gas supply unit that vents gas from the bottom surface side to the top surface side of the shelf plate, and the liquid and the liquid on the shelf plate A plate tower that makes contact with gas,
The liquid supply unit is configured to supply liquid to one side of the shelf board,
The shelf plate is provided with an outflow portion that causes the liquid on the shelf plate to flow downward on the other side,
On the shelf, a weir is provided on one side of the shelf from the outflow portion,
On one side of the shelf board from the weir of the shelf board, a guide unit for guiding the gas vented from the gas supply unit onto the shelf board is provided,
On the shelf plate, a perforated plate is provided that forms a gas flow path communicating with the guide portion between the shelf plate and allows gas to flow out from the flow path above the shelf plate,
The perforated plate is provided with a weir-side extension portion extending from the guide portion located closest to the weir side among the guide portions to the weir side,
A shelf tower, wherein the dam side extending part is provided with a gas blocking part that blocks the gas from flowing out from the dam side to the upper side of the shelf board from the position.   The gas blocking part is provided so as to block the gas from flowing out above the shelf plate from the weir side from the guide part located closest to the weir side among the guide parts. The plate tower according to claim 1. A shelf plate, a liquid supply unit that supplies liquid onto the shelf plate, and a gas supply unit that vents gas from the bottom surface side to the top surface side of the shelf plate, and the liquid and the liquid on the shelf plate A plate tower that makes contact with gas,
The liquid supply unit is configured to supply liquid to one side of the shelf board,
The shelf plate is provided with an outflow portion that causes the liquid on the shelf plate to flow downward on the other side,
On the shelf, a weir is provided on one side of the shelf from the outflow portion,
On one side of the shelf board from the weir of the shelf board, a guide unit for guiding the gas vented from the gas supply unit onto the shelf board is provided,
On the shelf plate, a perforated plate is provided that forms a gas flow path communicating with the guide portion between the shelf plate and allows gas to flow out from the flow path above the shelf plate,
The perforated plate is arranged on the shelf plate without extending the side end portion on the dam side from the guide portion located closest to the dam side among the guide portions to the dam side. A characteristic tower tower.   The guide portion includes an opening formed in the shelf plate, a tube portion that communicates with the opening and extends on the shelf plate, penetrates the porous plate, and is disposed above the tube portion. 2. A covered cylindrical bubble bell that covers the upper opening of the tube without closing, and communicates with the upper opening and forms a guide path that communicates with the flow path. The plate tower as described in any one of -3.

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