CN200948402Y - Ammonia synthesis air-releasing equal pressure recycling tower - Google Patents
Ammonia synthesis air-releasing equal pressure recycling tower Download PDFInfo
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- CN200948402Y CN200948402Y CN 200620107254 CN200620107254U CN200948402Y CN 200948402 Y CN200948402 Y CN 200948402Y CN 200620107254 CN200620107254 CN 200620107254 CN 200620107254 U CN200620107254 U CN 200620107254U CN 200948402 Y CN200948402 Y CN 200948402Y
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- ammonia
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Abstract
The utility model relates to a synthetic ammonia periodic off-gas equal-pressure recovery tower. An ammonia-water discharge tube, a periodic air inlet and outlet and a soft water inlet are arranged outside the tower wall; the tower cavity is separated into a plurality of two types of unit layers by a plurality of tower plates in the tower. The utility model is characterized in that a plurality of heat exchange unit layers are arranged in the tower at intervals; a heat exchanger is directly arranged in the heat exchange unit layers; a plurality of axial through holes are densely arranged on the tower plate of the absorption unit layer; each through hole is provided with a bubble cap; the bubble cover comprises a vertical gas raising channel and a peripheral housing. Since the external heat exchanger is changed into the built-in heat exchanger and is arranged according to the ammonia and water reaction property, the dissolving heat can be discharged in time, so as to enable uniform temperature distribution and good cooling effect in the tower; moreover, the bubble cover is used to replace the structure of the prior gas raising tube, so as to greatly increase the reaction area of ammonia and water; the ammonia concentration at the improved tower top periodic off-gas outlet is less than 0.5%; the ammonia-water concentration is around 25%; therefore, the effect is obvious.
Description
Technical field
The utility model relates to easy dissolved gas and reclaims, and the bigger a kind of chemical industry equipment of heat of solution, especially belongs in the liquefied ammonia production process, is used to reclaim the isobaric recovery tower of ammonia synthesis purge gas.
Background technology
In the liquefied ammonia production process, usually there are hydrogen, nitrogen and three kinds of gases of methane to exist in the synthetic tower, hydrogen and nitrogen are used for synthetic liquefied ammonia, but methane does not participate in reaction, therefore, along with the continuous accumulation of methane, just need discharging regularly during to finite concentration, this gas that has methane is ammonia synthesis purge gas.Except that containing methane, contain a large amount of ammonias toward contact in speeding to exit, ammonia is the gas under the liquefied ammonia product vaporized state, promptly gets the liquefied ammonia product after the recovery, if its discharging is not only also polluted the environment unfortunately.Isobaric recovery tower is exactly a kind of equipment that is used to reclaim ammonia, and it is speeded to exit up exporting to be connected in series by pipeline and ammonia convertor and communicates, and the ammonia synthesis purge gas atmospheric valve is used to control the discharging of speeding to exit in the loop.
In the public technology a kind of application more widely isobaric recovery tower structure as shown in Figure 1, Fig. 1 is the outer shape and the internal structure schematic diagram of this tower, and the size of tower is different with change of production, and the profile of tower generally is vertical shape, the tower outer wall is respectively equipped with from lower to upper: ammoniacal liquor delivery pipe 1, bottom ammoniacal liquor import 1B, the import 3A that speeds to exit, one deck ammoniacal liquor outlet 1A, soft water import 4, speeding to exit exports 3B, and two layers of ammoniacal liquor export 2A, one deck ammoniacal liquor import 2B.The blast pipe of exitting of speeding of import 3A and synthetic tower of speeding to exit communicates.Be connected in series external heat exchanger between one deck ammoniacal liquor outlet 1A and the bottom ammoniacal liquor import 1B, also be connected in series external heat exchanger between two layers of ammoniacal liquor outlet 2A and one deck ammoniacal liquor import 2B, the external heat exchanger that do not draw among the figure, the purpose of serial connection external heat exchanger are to solve in the ammonia removal process to produce a large amount of heats.
The tower inner structure: some blocks of column plates 5 are separated into several absorptive unit layers with space in the tower, every interlayer is established downspout 6 from top to bottom, the outlet of downspout 6 communicates with following one deck, and until tower two layer 7 has the gap between the liquid outlet 61 of downspout 6 and the column plate 5 on its top.In addition, every layer is provided with riser 8 from lower to upper, and riser import 81 is located at down one deck, and riser 8 crooked backs form the bottom tube 82 of a tiling, and the upper wall of bottom tube 82 has a lot of ventholes.
The reaction that ammonia is dissolved in the water has following characteristic: solubility is about 1: 700 under the normal temperature and pressure, and solution temperature is low more favourable more to dissolving, and the heat of solution of ammonia in water is very big, and the big more heat of solution that produces of meltage is just big more.The course of work of this tower is as follows:
1, the venting of speeding: carrying speeding to exit and speeding to exit after import 3A enters the tower bottom of ammonia from the tower bottom, enter in the last layer riser 8 from riser import 81, be folded to bottom tube 82 then, go out with liquid from the venthole of bottom tube 82 and to mix that (Fig. 1 is only at the top layer liquid that drawn, in fact from top layer to two layers 7, each layer all has corresponding liquid), liquid combines with ammonia and generates ammoniacal liquor, owing to just entered the interior ammonia ratio height of exitting of speeding of tower, which floor reaction below tower is also fierce especially, the heat of release also many especially (heat exchanger being set with regard to this reason at bottom), speed to exit come out from the liquid level of one deck after, enter in two layer 7 by the riser import again, then, in layer toward rising, ammonia is successively absorbed, and content is more and more lower, and is final, and the venting outlet 3B that speeds that speeds to exit from cat head is discharged to subsequent processing.
2, liquid: soft water enters from soft water import 4, flow on the top layer column plate 5, when liquid level exceeds the liquid outlet 61 of downspout 6, overflow and flow to down one deck, until flow to two layer 7 through two layers of ammoniacal liquor outlet 2A by the external heat exchanger cooling after one deck ammoniacal liquor import 2B flow in one deck, lowered the temperature after bottom ammoniacal liquor import 1B flows to bottom by external heat exchanger through one deck ammoniacal liquor outlet 1A, bottom ammoniacal liquor is discharged through ammoniacal liquor delivery pipe 1 again.
There is following defective in above-mentioned in actual applications ammonia isobaric recovery tower: Temperature Distribution is extremely inhomogeneous in the tower, there is not the column plate temperature of heat exchange very high, have a strong impact on the dissolving of ammonia in water, cooling-down effect is poor, the venting of speeding is long-pending little at Ta Nei and liquid contact surface, is about 5% from the ammonia level of speeding exitting of speeding to exit that outlet 3B discharges of cat head; The rate of recovery is low, and the ammonia concn of recovery is about 12%.
Summary of the invention
For overcoming the above-mentioned defective that prior art exists, the utility model aims to provide a kind of ammonia synthesis purge gas isobaric recovery tower with new structure, and this tower has good cooling effect, the venting gas-liquid full contact in tower of speeding, the ammonia concentration of discharging is low, the high advantage of ammonia recovery in the ammoniacal liquor.
For achieving the above object, the utility model has adopted following technical scheme: the structure of this ammonia synthesis purge gas isobaric recovery tower comprises heat exchanger, and is located at the ammoniacal liquor delivery pipe on the tower outer wall, and speeding, venting is imported and exported, the soft water import; Be separated into several layers absorptive unit layer by some column plate tower chambeies in the tower, it is characterized in that: compartment has been set up the heat exchange unit layer in the tower chamber, and heat exchanger directly is seated in this heat exchange unit layer; Densely covered axially extending bore on the column plate of absorptive unit layer, each through hole is provided with a bubble-cap; Bubble-cap is by the air flue that rises of vertical shape, and is buckled in its peripheral case two parts and constitutes, and the case base wall is provided with venthole.
The density that is provided with of compartment is gradually little from lower to upper for the heat exchange unit layer.
The utility model in the specific implementation, venthole is shaped as the stria of axial setting on the bubble-cap.
Beneficial effect: compared with prior art, the utility model has been owing to made external heat exchanger into built-in heat exchanger, and according to the response characteristic of ammonia and water and the reaction of bottom, tower chamber is fierce, the actual conditions more than the release heat are provided with built-in heat exchanger.Heat exchange at the bottom of the old tower employing tower, cat head raises gradually to column bottom temperature, all heats focus on two blocks of last column plates, and (the above temperature of the 3rd block of column plate is still very high, the raising of the concentration of ammoniacal liquor at the bottom of the tower and the reduction of tower top outlet ammonia concentration have been limited to a great extent), the effect of external heat exchanger just will absorb the ammonia temperature that finishes and lower, can not play the effect that improves ammonia concn, new tower adopts heat exchange in the tower, heat exchanger distributes in tower, in time the absorption heat of each column plate is removed, make the temperature of whole tower keep even relatively, do not have the too high phenomenon that influences assimilation effect of temperature.
Moreover, substituted original riser structure with bubble-cap, adopt bubble cap plate, liquid gas contact area increases, and has increased the response area of ammonia G﹠W greatly, and absorbability is strengthened, every layer of column plate liquid level of Xin Taxinta is about 120mm, arrive the resistance little (every layer of column plate liquid level of old tower is about 700mm, and SR is big, cat head and tower bottom pressure skewness) of tower at the bottom of the tower.
At last, new tower heat exchanger liquid phase free convection from top to bottom, the needed motive force of liquid flow in the time of need not considering the heat exchange outward of old Tata.
Facts have proved: the cat head after the improvement is speeded venting outlet ammonia concentration less than 0.5%, and ammonia concn is about 25%, and effect is obvious.
The drawing explanation
Fig. 1 is the structural representation of a kind of isobaric recovery tower in the prior art;
Fig. 2 is the whole tower broken section structural representation of an embodiment of the utility model;
Fig. 3 is the amplification assumption diagram at A position among Fig. 2;
Fig. 4 is the heat exchange unit layer plan structure schematic diagram after dissecing along A-A among Fig. 2;
Fig. 5 is the plan structure schematic diagram of absorptive unit layer 10 among Fig. 3;
Fig. 6 is the structure for amplifying schematic diagram of bubble-cap 13 among Fig. 3.
The specific embodiment
Sequence number is respectively among the figure: ammoniacal liquor delivery pipe 1, one deck ammoniacal liquor outlet 1A, bottom ammoniacal liquor import 1B, two layers of ammoniacal liquor outlet 2A, one deck ammoniacal liquor import 2B, import 3A speeds to exit, the venting outlet 3B that speeds, soft water import 4, liquid level 41, column plate 5, downspout 6, the downspout mouth of pipe 61, two layer 7, riser 8, the riser mouth of pipe 81, bottom tube 82; Absorptive unit layer 10, heat exchanger 11, heat exchanger cooling water inlet 11a, liquid left clapboard 12 falls in heat exchanger coolant outlet 11b, falls liquid right clapboard 121, bubble-cap 13, tower wall 14 rises air bound plate 15, rise gas passage 151, heat exchange unit layer 16 rises air flue 17, rise gas port 171, registration arm 172, case 18, venthole 181.
Fig. 2 shows the whole tower broken section structure of an embodiment.This tower profile is originally identical with the column foot of prior art Fig. 1, and ammoniacal liquor delivery pipe 1 is established in the tower bottom, and nearly bottom is established and speeded to exit import 3A, soft water import 4 is established on top, cat head is established the venting outlet 3B that speeds, and the venting outlet 3B that speeds goes up the same tower pressure regulator valve that is provided with prior art, is used to regulate the tower cavity pressure.
Referring to Fig. 3, and in conjunction with Fig. 4, Fig. 5.Fig. 3 is the partial enlarged drawing of A portion among Fig. 2, and it shows the structure of two heat exchange unit layers 16 and an absorptive unit layer 10, and the tower inner structure is made of the heat exchange unit layer 16 and the absorptive unit layer 10 of compartment.
So-called compartment setting is exactly heat exchange unit layer 16 and the 10 interlaced setting of absorptive unit layer, certainly, if consider that in the bottom of tower heat is many, also several heat exchange unit layers 16 can be set continuously, setting principle can consider that in general density is big at the bottom of the tower, and is more little to upper density more according to the graded situation of heat, heat exchange unit layer 16 can be established less, does not even establish.
Be provided with heat exchanger 11 in the heat exchange unit layer 16, vertical shape is respectively equipped with and falls liquid left clapboard 12 on the position, the left and right sides of heat exchanger 11, falls liquid right clapboard 121, falls liquid dividing plate and inner wall of tower formation and falls the liquid passage.Fall the liquid passage and be the right setting of a first from left, haircut express liquid among Fig. 3 is the soft water flow direction, in layer past dirty from the soft water that soft water import 4 enters, if the absorptive unit layer 10 of flowing through just reacts with the venting of speeding of coming out from bubble-cap 13, ammonia and water generate ammoniacal liquor and also emit heat; When flowing through heat exchange unit layer 16, liquid continues stream downwards after by the cooling water temperature in the heat exchanger, until discharging this tower from ammoniacal liquor delivery pipe 1.
The venting of speeding of reacting with soft water is exitted from speeding after import 3A advances tower, successively rises from lower to upper.During to heat exchange unit layer 16, then to rise to this layer top (be the below of the column plate 5 of absorptive unit layer 10 from the gas passage 151 (referring to Fig. 4) that rises that rises that air bound plate 15 and inner wall of tower surround, be provided with continuously if which floor heat exchange unit layer 16 is, then continue to rise) along the corresponding gas passage 151 that rises.
Referring to Fig. 6, bubble-cap 13 is made of rising air flue 17 and being connected its peripheral case 18 of vertical shape, and case 18 is fixed on the tube wall that rises air flue 17 through securing member by registration arm 172.
The venting of speeding of lower floor enters and rises air flue 17 from rising gas port 171, arrives to be folded to the bottom behind the top under case 18 effects and to come out from venthole 181, with the contact lysis of soft water layer.Because a lot of bubble-caps 13 are evenly distributed on the column plate 5, the peripheral bottom of bubble-cap 13 nearly bottoms is equipped with venthole 181, and it is shaped as vertically to the stria that is provided with, compared with prior art total area of giving vent to anger obviously increases, gas can be contacted fully with soft water, thereby improved its meltage in soft water greatly.
Claims (3)
1, a kind of ammonia synthesis purge gas isobaric recovery tower, its structure comprise heat exchanger (11), and are located at the ammoniacal liquor delivery pipe (1) on the tower outer wall, and (3A, 3B), soft water import (4) are imported and exported in the venting of speeding; By some blocks of column plates (5) the tower chamber is separated into several layers absorptive unit layer (10) in the tower, it is characterized in that: compartment has been set up heat exchange unit layer (16) in the tower chamber, and heat exchanger (11) directly is seated in this heat exchange unit layer (16); Densely covered axially extending bore on the column plate of absorptive unit layer (10), each through hole is provided with a bubble-cap (13); Bubble-cap (13) rises air flue (17) by vertical shape, and is buckled in its peripheral case (18) two parts and constitutes, and the ring wall of case (18) base portion is provided with venthole (181).
2, described isobaric recovery tower as claimed in claim 1 is characterized in that: the density that is provided with of compartment is gradually little from lower to upper for heat exchange unit layer (16).
3, described isobaric recovery tower as claimed in claim 1 is characterized in that: being shaped as of bubble-cap venthole (181) is vertical to the stria that is provided with.
Priority Applications (1)
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CN 200620107254 CN200948402Y (en) | 2006-08-26 | 2006-08-26 | Ammonia synthesis air-releasing equal pressure recycling tower |
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CN 200620107254 CN200948402Y (en) | 2006-08-26 | 2006-08-26 | Ammonia synthesis air-releasing equal pressure recycling tower |
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CN200948402Y true CN200948402Y (en) | 2007-09-19 |
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CN 200620107254 Expired - Fee Related CN200948402Y (en) | 2006-08-26 | 2006-08-26 | Ammonia synthesis air-releasing equal pressure recycling tower |
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Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN112316672A (en) * | 2020-11-05 | 2021-02-05 | 中盐昆山有限公司 | Washing tower for filtering tail gas |
CN115582381A (en) * | 2022-10-14 | 2023-01-10 | 山东大学 | Gas purification device and process |
-
2006
- 2006-08-26 CN CN 200620107254 patent/CN200948402Y/en not_active Expired - Fee Related
Cited By (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN112316672A (en) * | 2020-11-05 | 2021-02-05 | 中盐昆山有限公司 | Washing tower for filtering tail gas |
CN115582381A (en) * | 2022-10-14 | 2023-01-10 | 山东大学 | Gas purification device and process |
CN115582381B (en) * | 2022-10-14 | 2024-05-24 | 山东大学 | Gas purifying device and process |
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C14 | Grant of patent or utility model | ||
GR01 | Patent grant | ||
C17 | Cessation of patent right | ||
CF01 | Termination of patent right due to non-payment of annual fee |
Granted publication date: 20070919 Termination date: 20110826 |