CN108910921A - A kind of system and method preparing magnesium sulfate using flue gas heat-source Cycles - Google Patents

Abstract

The present invention relates to a kind of system and methods that magnesium sulfate is prepared using flue gas heat-source Cycles, belong to flue gas desulfurization technique field.The system comprises：Desulfurizing tower, heating device, deduster, heat exchanger, slurry pool, sparge pipe；The deduster is connect with heating device, the lower part connection of heating device and desulfurizing tower；The bottom of the desulfurizing tower is connect with heat exchanger, and heat exchanger is connect with heating device；The heating device is connect with heat exchanger, and heat exchanger, slurry pool, sparge pipe are sequentially connected, and the top of desulfurizing tower is protruded into one end of sparge pipe.The present invention using with the subsequent evaporation crystallization treatment technique by the way of flue gas heat exchange instead of Adlerika, not only simplify the preparation process of desulfuration byproduct, the energy consumption in evaporative crystallization processing is saved, and realizes the effective use of residual heat resources, flue gas is made to have obtained high value added utilization.

Description

A kind of system and method preparing magnesium sulfate using flue gas heat-source Cycles

Technical field

The present invention relates to flue gas desulfurization technique field more particularly to a kind of fume afterheats using thermal power plant, in magnesium Circulation prepares the system and method for magnesium sulfate in method sweetening process.

Background technique

Magnesium method flue gas desulphurization technique is a kind of Wet Flue Gas Desulfurization Technique for carrying out flue gas desulfurization as desulfurizing agent using magnesia, The desulphurization mechanism of magnesia is that basic anhydride and water react and generates hydroxide, and hydroxide slurry reabsorbs in flue gas SO₂, generate aqueous magnesium sulfite and a small amount of magnesium sulfate.The direct by-product of magnesium method flue gas desulphurization is three water and six water sulfurous acid Magnesium, since there are oxygen (O in flue gas₂), magnesium sulfite will be oxidized to magnesium sulfate under certain condition.

Magnesium processes desulfurization technology maturation is reliable, and desulfuration efficiency is high, and byproduct can comprehensively utilize, it is shown that increasing is excellent More property.There is data to show, at present the U.S., Europe, Japanese Thermal Power Plants 80% unit capacity be all made of magnesium processes desulfurization, TaiWan, China 95% unit capacity of power plant is also using magnesium processes desulfurization.Magnesium processes desulfurization has following features：(1) magnesium that magnesium method flue gas desulphurization uses Agent desulfurizing agent is very stronger than reactivity, and much higher than the reactivity of calcium agent 10 times, desirable higher desulfuration efficiency generally exists 95% or more, the consuming cost of desulfurizing agent reduces.(2) while desulfuration operations are stablized, small investment, due to magnesium processes desulfurization by-product Object cigarette magnesium sulfate, magnesium sulfate have higher solubility, so as to avoid its in systems fouling, blocking the problems such as generation.

However, in existing magnesium method flue gas desulphurization technique, it generally first will be in flue gas with desulfurizing agent (such as magnesium hydroxide solution) Sulfur dioxide removal, obtain being post-processed to obtain sulfuric acid magnesium products after Adlerika to it again, what this method generated Problem is：Aqueous solvent in desulfurizing agent largely evaporates in desulfurizing tower, and aqueous solvent not only causes water resource after being discharged with flue gas A large amount of wastes will cause serious plume contamination after being expelled directly out, so that enterprise has to and since smoke moisture is excessive It is additional to install flue gas dehumidification equipment additional, make entire process complications, the high cost of flue gas desulfurization.Therefore, it is necessary to study one kind New magnesium processes desulphurization system, to solve above-mentioned problems of the prior art.

Summary of the invention

For above-mentioned problems of the prior art, the present invention is intended to provide a kind of prepare sulphur using flue gas heat-source Cycles The system and method for sour magnesium.The present invention realizes following for magnesium processes desulfurization using heat source abundant in magnesium processes desulfurization technology and flue gas While ring carries out and the low cost of magnesium sulfate, high efficiency preparation, the high value added utilization of flue gas is also achieved.

An object of the present invention is to provide a kind of system for preparing magnesium sulfate using flue gas heat-source Cycles.

The second object of the present invention is to provide a kind of method for preparing magnesium sulfate using flue gas heat-source Cycles.

The third object of the present invention is to provide a kind of magnesium sulfate prepared using flue gas heat-source Cycles.

The fourth object of the present invention, which is to provide, to be prepared the system of magnesium sulfate, method using flue gas heat-source Cycles and utilizes cigarette The application of the magnesium sulfate of gas heat-source Cycles preparation.

For achieving the above object, specifically, the invention discloses following technical proposals：

Firstly, the invention discloses a kind of system for preparing magnesium sulfate using flue gas heat-source Cycles, the system comprises：It is de- Sulphur tower, Adlerika pump, heating device, air-introduced machine, deduster, heat exchanger, slurry pool, desulfurizing agent solution pump, sparge pipe.

The deduster, air-introduced machine, heating device are sequentially connected, and heating device is connected with the lower part of desulfurizing tower.Flue gas warp After crossing deduster dedusting, it is sent into heating device by air-introduced machine, is exchanged heat with Adlerika therein, the flue gas after heat exchange Temperature is greatly lowered, and then enters from the lower part of desulfurizing tower and carries out desulfurization in desulfurizing tower.

The flue gas comes from thermal power plant, because thermal power plant possesses DEG C various temperature gradients from 100 DEG C to 800 Heat source, residual heat resources are abundant, can cooperate with magnesium processes desulfurization, realize the high value added utilization of flue gas.

The slurry pool and desulfurizing agent solution pump connect, and one end of sparge pipe and desulfurizing agent solution pump connect, and the other end is stretched Enter the top of desulfurizing tower.Contain desulfurizing agent solution in the slurry pool, desulfurizing agent solution is sent into sparge pipe by desulfurizing agent solution pump In, then sprayed from up to down from the top of desulfurizing tower by sparge pipe, and the flue gas after exchanging heat is sailed against the current from the lower part of desulfurizing tower, It is contacted with desulfurizing agent solution, to complete the desulfurization of flue gas, the flue gas after desulfurization is directly by smoke stack emission, and desulfurizing agent solution passes through Become congregate of the Adlerika to desulfurizing tower after crossing desulfurization.

The bottom of the desulfurizing tower, Adlerika pump, heat exchanger, heating device are sequentially connected；The sulphur of desulfurization tower bottom Sour magnesium solution is admitted in heat exchanger by Adlerika pump, is exchanged heat with water vapour therein, thus molten to magnesium sulfate Liquid preheating, the Adlerika after preheating enters heating device, molten to magnesium sulfate using the flue gas (heat source) by heating device Liquid is heated, and the aqueous solvent in Adlerika is by thermal evaporation, thus the magnesium sulfate finished product crystallized.

Preferably, the heat exchanger uses dividing wall type structure, and the inside of the dividing wall type structure is hollow structure, vapor Pass through from hollow dividing wall type structure, for Adlerika between dividing wall type structure, the wall by dividing wall type structure is complete It is exchanged at the heat between vapor and Adlerika, and then Adlerika is preheated.

Preferably, the sour magnesium finished product also recyclable Adlerika import to heating device of heating device preparation, changes The kind magnesium sulfate concentration into heating device, further increases magnesium sulfate quality and heat recovery.

The heating device, heat exchanger, slurry pool are sequentially connected.Shape of the aqueous solvent after by thermal evaporation in Adlerika At water vapour enter heat exchanger from heating device, to be preheated to Adlerika, after preheating, water recovery at Then condensed water is reintroduced in slurry pool, be configured to desulfurizing agent solution with desulfurizing agent and recycled.

Preferably, the heating device uses dividing wall type structure, and the inside of the dividing wall type structure is hollow structure, flue gas Pass through from hollow dividing wall type structure, for Adlerika between dividing wall type structure, the wall by dividing wall type structure is complete It is exchanged at the heat between flue gas and Adlerika, and then Adlerika is dehydrated, using fume afterheat to sulfuric acid Magnesium solution, which is dehydrated, to be advantageous in that：The waste heat in flue gas can not only be efficiently used, and desulfurizing tower can be lowered into Flue-gas temperature further decrease discharge to reduce the evaporation capacity of moisture in desulfurizing tower (desulfurizing agent solution, Adlerika) The water capacity of flue gas reduces plume contamination.

Secondly, including the following steps the invention also discloses a kind of method for preparing magnesium sulfate using flue gas heat-source Cycles：

(1) first flue gas is sent into heating device after deduster dedusting by air-introduced machine, is then fed into desulfurizing tower and carries out Desulfurization；Meanwhile the desulfurizing agent solution in slurry pool is sent into sparge pipe by desulfurizing agent solution pump, is sprayed from up to down through sparge pipe Afterwards, and from the upstream smoke contacts of desulfurization tower bottom, desulfurization is completed, and desulfurizing agent solution is transformed into Adlerika to de- Collect the bottom of sulphur tower；

(2) Adlerika in step (1) is sent into heat exchanger by Adlerika pump preheats, and send again after preheating Enter in heating device, Adlerika is heated with fume afterheat, the aqueous solvent in Adlerika is formed by thermal evaporation Water vapour obtains magnesium sulfate finished product；

(3) water vapour in step (2) enters in heat exchanger, preheats to the Adlerika in desulfurizing tower, After preheating then water recovery is reintroduced in slurry pool at condensed water, is configured to desulfurizing agent solution with desulfurizing agent and is carried out It recycles.

Finally, the invention also discloses prepare the system of magnesium sulfate using flue gas heat-source Cycles, utilize flue gas heat-source Cycles The magnesium sulfate of the method, flue gas heat-source Cycles magnesium processes desulfurization preparation that prepare magnesium sulfate is in food, chemical industry, medicine, agriculture field Application.

It should be noted that：The main object of the present invention is while realizing prepared by magnesium sulfate using waste heat in flue gas, also Realize the circulation of magnesium processes sulfur removal technology, it means that have to realize the Adlerika obtained after desulfurizing agent solution and desulfurization Otherwise the recycling of middle aqueous solution can not really realize circulation magnesium processes desulfurization this purpose；It is found after analysis：Desulfurizing agent is molten The loss of aqueous solvent is concentrated mainly on the sweetening process in desulfurizing tower in liquid and Adlerika, because the smoke temperature of flue gas is very Height is directly entered after contacting in desulfurizing tower with the Adlerika obtained after desulfurizing agent solution and desulfurization, aqueous solution therein It can largely be evaporated, and then be discharged with flue gas, both wasted the residual heat resources in flue gas, wasted a large amount of water resource, and And the water capacity that flue gas is discharged is too big, can generate obviously plume phenomenon in discharge, bring serious visual pollution.

To solve the above-mentioned problems, the present invention just significantly cools down to it first before flue gas enters desulfurizing tower, The waste heat of flue gas is used to heat desulfurization product (magnesium sulfate solution) to prepare magnesium sulfate, to eliminate Adlerika Subsequent processing directly obtains magnesium sulfate finished product, after the flue gas after cooling enters desulfurizing tower, evaporates the ability of aqueous solvent significantly It reduces, the evaporation of aqueous solvent in desulfurizing tower can be effectively reduced, not only reduce the waste of water resource, also reduce discharge flue gas Water capacity, effectively improve pollution caused by flue gas, simultaneously as discharge flue gas water capacity sharp fall, Ke Yizhi Run in sky, is not required to carry out subsequent processing again to avoid plume phenomenon.And magnesium sulfate solution is entering after heat exchanger preheats Just there is certain temperature before heating device, into after heating device, the solute water in Adlerika is in steam source Heating under can fast and efficiently evaporate, magnesium sulfate finished product is directly obtained, to eliminate the subsequent place of Adlerika Reason, and the water-soluble matter in Adlerika is introduced back into slurry pool after being evaporated, exchanging heat and is recycled, to realize The recycling of water resource avoids the waste of water resource；As can be seen that the waste heat and letter of the invention just in flue gas Single circulation, cooling, heat transfer process efficiently solve a large amount of waves of fume afterheat resource and water resource in magnesium processes sweetening process The problem taken achieves extraordinary synergy.

Compared with prior art, the beneficial effect that the present invention obtains is：

(1) present invention using with the subsequent evaporation crystallization treatment technique by the way of flue gas heat exchange instead of Adlerika, The preparation process for not only simplifying desulfuration byproduct saves the energy consumption in evaporative crystallization processing, and realizes residual heat resources Effective use, so that flue gas has been obtained high value added utilization.

(2) heat in water vapour of the present invention such as can be used for heating after being exchanged heat the purposes, make waste heat in flue gas again It is utilized, meanwhile, condensed water vapour is used again to desulfurization, not only realizes circulation magnesium processes desulfurization, is also effectively improved Plume phenomenon, by system of the invention, treated after flue gas directly empties, and plume phenomenon naked eyes are invisible.

Detailed description of the invention

The accompanying drawings constituting a part of this application is used to provide further understanding of the present application, and the application's shows Meaning property embodiment and its explanation are not constituted an undue limitation on the present application for explaining the application.

Fig. 1 is the structural schematic diagram for preparing magnesium sulfate system in the embodiment of the present invention 1 using flue gas heat-source Cycles.

Fig. 2 is the structural schematic diagram for preparing magnesium sulfate system in the embodiment of the present invention 2 using flue gas heat-source Cycles.

Attached drawing acceptance of the bid note respectively represents：1- desulfurizing tower, 2- Adlerika pump, 3- heating device, 4- air-introduced machine, 5- dedusting Device, 6- heat exchanger, 7- slurry pool, 8- desulfurizing agent solution pump, 9- sparge pipe.

Specific embodiment

It is noted that following detailed description is all illustrative, it is intended to provide further instruction to the application.Unless another It indicates, all technical and scientific terms used herein has usual with the application person of an ordinary skill in the technical field The identical meanings of understanding.

It should be noted that term used herein above is merely to describe specific embodiment, and be not intended to restricted root According to the illustrative embodiments of the application.As used herein, unless the context clearly indicates otherwise, otherwise singular Also it is intended to include plural form, additionally, it should be understood that, when in the present specification using term "comprising" and/or " packet Include " when, indicate existing characteristics, step, operation, device, component and/or their combination.

As background technique is introduced, existing magnesium processes sulfur removal technology still has a large amount of wastes, serious of water resource Plume contamination and complex process, it is at high cost the problems such as, therefore, the invention proposes it is a kind of using flue gas heat-source Cycles prepare The system and method for magnesium sulfate, the present invention is described further with reference to the accompanying drawings and detailed description.

Embodiment 1

As shown in Figure 1, a kind of system for preparing magnesium sulfate using flue gas heat-source Cycles, the system comprises：Desulfurizing tower 1, Adlerika pump 2, heating device 3, air-introduced machine 4, deduster 5, heat exchanger 6, slurry pool 7, desulfurizing agent solution pump 8, sparge pipe 9。

The deduster 5, air-introduced machine 4, heating device 3 are sequentially connected, and heating device 3 is connected with the lower part of desulfurizing tower 1.Cigarette Gas is sent into heating device 3 by air-introduced machine, is exchanged heat with Adlerika therein, after heat exchange after deduster dedusting Flue-gas temperature reduce, then enter from the lower part of desulfurizing tower 1 and carry out desulfurization in desulfurizing tower 1.

The slurry pool 7 is connect with desulfurizing agent solution pump 8, and one end of sparge pipe 9 is connect with desulfurizing agent solution pump 8, another The top of desulfurizing tower 1 is protruded at end.Contain desulfurizing agent solution in the slurry pool 7, desulfurizing agent solution is sent by desulfurizing agent solution pump In sparge pipe 9, then sprayed from up to down from the top of desulfurizing tower by sparge pipe 9, and the flue gas after exchanging heat is from the lower part of desulfurizing tower 1 It sails against the current, is contacted with desulfurizing agent solution, to complete the desulfurization of flue gas, the flue gas after desulfurization takes off directly by smoke stack emission Sulphur agent solution becomes Adlerika to the congregate of desulfurizing tower 1 after desulfurization.

The bottom of the desulfurizing tower 1, Adlerika pump 2, heat exchanger 6, heating device 3 are sequentially connected；1 bottom of desulfurizing tower Adlerika 2 be admitted in heat exchanger 6 by Adlerika pump, exchange heat with water vapour therein, thus to sulphur Sour magnesium solution preheating, the Adlerika after preheating enters heating device 3, right using the flue gas (heat source) for passing through heating device 3 Adlerika is heated, and the aqueous solvent in Adlerika is by thermal evaporation, thus the magnesium sulfate finished product crystallized.

The heating device 3, heat exchanger 6, slurry pool 7 are sequentially connected.Aqueous solvent in Adlerika is after by thermal evaporation The water vapour of formation enter heat exchanger 6 from heating device 3, to be preheated to Adlerika, after preheating, water vapour Condensed water is condensed, is then reintroduced in slurry pool 7, is configured to desulfurizing agent solution with desulfurizing agent and is recycled.

The heating device 3 uses dividing wall type structure, and the inside of the dividing wall type structure is hollow structure, and flue gas is from hollow Dividing wall type structure in pass through, Adlerika completes flue gas between dividing wall type structure, through the wall of dividing wall type structure Heat between Adlerika exchanges.

The heat exchanger 6 uses dividing wall type structure, and the inside of the dividing wall type structure is hollow structure, and vapor is from hollow Dividing wall type structure in pass through, Adlerika is completed water by the wall of dividing wall type structure and is steamed between dividing wall type structure Heat between gas and Adlerika exchanges, and then preheats to Adlerika.

Embodiment 2

As shown in Fig. 2, a kind of flue gas heat-source Cycles magnesium processes desulfurization and magnesium sulfate preparation system, the system with embodiment 1, 20% magnesium sulfate finished product of heating device preparation is recycled to the Adlerika import of heating device 3, to improve granulation matter Amount and heat recovery.

The foregoing is merely preferred embodiment of the present application, are not intended to limit this application, for those skilled in the art For member, various changes and changes are possible in this application.Within the spirit and principles of this application, it is made it is any modification, Equivalent replacement, improvement etc., should be included within the scope of protection of this application.

Claims (10)

1. a kind of system for preparing magnesium sulfate using flue gas heat-source Cycles, it is characterised in that：The system comprises：Desulfurizing tower adds Thermal, deduster, heat exchanger, slurry pool, sparge pipe；The deduster is connect with heating device, heating device and desulfurizing tower Lower part connection；The bottom of the desulfurizing tower is connect with heat exchanger, and heat exchanger is connect with heating device；The heating device with change Hot device connection, heat exchanger, slurry pool, sparge pipe are sequentially connected, and the top of desulfurizing tower is protruded into one end of sparge pipe.

2. the system for preparing magnesium sulfate using flue gas heat-source Cycles as described in claim 1, it is characterised in that：The system is also Including air-introduced machine, the deduster, air-introduced machine, heating device are sequentially connected.

3. the system for preparing magnesium sulfate using flue gas heat-source Cycles as claimed in claim 2, it is characterised in that：The system is also It is pumped including Adlerika, the bottom of the desulfurizing tower, Adlerika pump, heat exchanger are sequentially connected.

4. the system for preparing magnesium sulfate using flue gas heat-source Cycles as claimed in claim 3, it is characterised in that：The system is also It is pumped including desulfurizing agent solution；The heat exchanger, slurry pool, desulfurizing agent solution pump are sequentially connected, one end of sparge pipe and desulfurizing agent Solution pump connection, the other end protrude into the top of desulfurizing tower.

5. the system according to any one of claims 1-4 for preparing magnesium sulfate using flue gas heat-source Cycles, it is characterised in that：Institute Heating device is stated using dividing wall type structure, the inside of the dividing wall type structure is hollow structure, and flue gas is from hollow dividing wall type knot Pass through in structure, Adlerika completes flue gas by the wall of dividing wall type structure and magnesium sulfate is molten between dividing wall type structure Heat exchange between liquid.

6. the system according to any one of claims 1-4 for preparing magnesium sulfate using flue gas heat-source Cycles, it is characterised in that：Institute Heat exchanger is stated using dividing wall type structure, the inside of the dividing wall type structure is hollow structure, and vapor is from hollow dividing wall type knot Pass through in structure, Adlerika completes vapor and magnesium sulfate between dividing wall type structure, through the wall of dividing wall type structure Heat exchange between solution.

7. the system according to any one of claims 1-4 for preparing magnesium sulfate using flue gas heat-source Cycles, it is characterised in that：Institute State the Adlerika import that magnesium sulfate finished product obtained in heating device is recycled to heating device.

8. a kind of method for preparing magnesium sulfate using flue gas heat-source Cycles, it is characterised in that：Include the following steps：

(1) first flue gas is sent into heating device after deduster dedusting by air-introduced machine, is then fed into desulfurizing tower and carries out desulfurization； Meanwhile desulfurizing agent solution pump by slurry pool desulfurizing agent solution be sent into sparge pipe, after sparge pipe sprays from up to down, with from The upstream smoke contacts of desulfurization tower bottom complete desulfurization, and desulfurizing agent solution is transformed into Adlerika to desulfurizing tower Collect bottom；

(2) Adlerika in step (1) is sent into heat exchanger by Adlerika pump preheats, and is re-fed into and adds after preheating In thermal, Adlerika is heated with fume afterheat, the aqueous solvent in Adlerika is formed water and steamed by thermal evaporation Vapour obtains magnesium sulfate finished product；

(3) water vapour in step (2) enters in heat exchanger, preheats to the Adlerika in desulfurizing tower, preheating Afterwards then water recovery is reintroduced in slurry pool at condensed water, is configured to desulfurizing agent solution with desulfurizing agent and is recycled It utilizes.

9. the magnesium sulfate of method according to claim 8 preparation.

10. using flue gas heat-source Cycles preparing the system of magnesium sulfate and/or as right is wanted as claim 1-7 is described in any item The application of method described in asking 8 and/or magnesium sulfate as claimed in claim 9 in food, chemical industry, medicine, agriculture field.