CN214611635U - Energy-saving evaporation concentration equipment for salt-containing wastewater - Google Patents

Abstract

An energy-saving evaporation concentration device for salt-containing wastewater comprises a salt-containing wastewater feeding pump (12), a condensing heat exchanger (13) and a normal-pressure low-temperature evaporation concentration device, and is characterized in that the main structure of the normal-pressure low-temperature evaporation concentration device consists of an evaporation chamber (1) and a spray chamber (7), a burner (3) is installed in the evaporation chamber and is provided with a combustion tail gas discharge pipe (2), the combustion tail gas discharge pipe is immersed in the wastewater, and the surface of the combustion tail gas discharge pipe is provided with a hole groove which is used as a high-temperature flue gas discharge port; the high-temperature flue gas directly contacts with the wastewater liquid for heat exchange, and the wastewater is heated until secondary steam is generated; the temperature of the flue gas is reduced, and the flue gas leaves the evaporation chamber along with the generated secondary steam and upwards enters the spray chamber to perform secondary heat exchange with the waste liquid sprayed out of the spray layer (8) and the air blown in by the air blower; the waste liquid after heat exchange with the flue gas is pumped into a spraying layer (8) through a feed liquid circulating pump (4). The utility model has the advantages of less scale formation, less corrosion, low cost and long service life.

Description

Energy-saving evaporation concentration equipment for salt-containing wastewater

Technical Field

The utility model relates to an environmental protection technology, especially a waste water treatment technology, specifically speaking are energy-conserving evaporation concentration equipment of salt waste water.

Background

The salt-containing wastewater mainly comes from chemical plants and the collection and processing processes of petroleum and natural gas, the generation path is wide, and the water quantity is increased year by year. At present, a near zero emission treatment process is generally adopted for treating salt-containing wastewater. The process consists of units such as pretreatment, membrane method preconcentration, evaporation concentration, crystallization and salt precipitation. Wherein, the evaporation concentration unit is a key step for reducing and recycling the salt-containing wastewater. Because of the existence of scaling ions in the salt content of the wastewater, the concentration is continuously enriched in the continuous evaporation and concentration process to reach the supersaturation degree, thereby forming salt scale on the heat exchange surface. The existence of salt scale not only greatly reduces the heat transfer efficiency of the evaporation concentration device, but also leads to system paralysis and abnormal operation in severe cases. Huge equipment cleaning and maintenance cost is required each year, and the wastewater treatment cost is increased. The existence of salt scale can also cause the under-scale corrosion symbiosis phenomenon, so that equipment is easy to corrode, and therefore, a high-grade corrosion-resistant metal material is required to be used, and the equipment investment cost is increased.

At present, the concentration of the salt-containing wastewater is 2-10% after pretreatment and membrane-method preconcentration. If the concentration ratio is further increased, the method is a challenge for a membrane method system. Besides the reduction of concentration efficiency, the pollution and blockage of a membrane system can be serious, the membrane cleaning frequency is increased, the service life of the membrane is greatly reduced, and the system operation cost can be greatly increased by replacing the membrane component, adding cleaning agents and the like. The process of re-concentrating the salt-containing wastewater adopts a conventional thermal evaporation technology, and multiple-effect evaporation and MVR evaporation technologies become mainstream for improving the thermal efficiency. But the improvement of the multi-effect evaporation heat efficiency is limited, and 3-5 effects are usually set. Although the MVR evaporation technology fully utilizes the enthalpy of secondary steam, the energy efficiency is further improved. However, the operation temperature of the two components is higher, so that the system is easy to generate scaling corrosion, and the long-period stable operation of the equipment is seriously influenced.

The bottleneck problem to be solved in the thermal evaporation concentration technology at present is the scaling and corrosion of equipment. The problem of concentration enrichment of the scaling ions cannot be fundamentally solved by pretreatment, and even if the concentration of the scaling ions is reduced to the minimum by dosing pretreatment, the additional expense of pretreatment medicament is needed.

SUMMERY OF THE UTILITY MODEL

The utility model aims at the current salt waste water treatment that contains handles at low temperature and produce the problem that the scale deposit influences normal operating, the utility model relates to a low temperature moves the difficult scale deposit, equipment corrosion resisting property is good, the energy-conserving evaporative concentration equipment of salt waste water that the running cost is low.

The technical scheme of the utility model is that:

an energy-saving evaporation concentration device for salt-containing wastewater comprises a salt-containingwastewater feeding pump 12, acondensing heat exchanger 13 and a normal-pressure low-temperature evaporation concentration device, wherein the pretreated salt-containing wastewater is pumped into the condensingheat exchanger 13 through one path of the salt-containingwastewater feeding pump 12 and then is sent into a spraying layer 8 on the upper part of the normal-pressure low-temperature evaporation concentration device, the other path of the pretreated salt-containing wastewater enters an evaporation chamber 1 of the normal-pressure low-temperature evaporation concentration device, thecondensing heat exchanger 13 and the normal-pressure low-temperature evaporation concentration device are communicated through aflue gas pipeline 10, the spraying layer 8 is positioned in theflue gas pipeline 10, a demister 9 and a wastegas adsorption device 11 are arranged in theflue gas pipeline 10 and on the upper part of the spraying layer 8, and the energy-saving evaporation concentration device is characterized in that the main structure of the normal-pressure low-temperature evaporation concentration device consists of the evaporation chamber 1 and the spraying chamber 7, a burner 3 is arranged in the evaporation chamber 1 and is provided with a combustion tail gas discharge pipe 2, and the combustion tail gas discharge pipe 2 is immersed in the wastewater, the surface of the combustion tail gas discharge pipe 2 is provided with a hole groove which is used as a high-temperature flue gas discharge port; the high-temperature flue gas directly contacts with the wastewater liquid for heat exchange, and the wastewater is heated until secondary steam is generated; the temperature of the flue gas is reduced, the flue gas leaves the evaporation chamber along with the generated secondary steam, and the flue gas upwards enters the spraying chamber 7 to perform secondary heat exchange with the waste liquid sprayed out of the spraying layer 8 and the air blown in by the air blower, so that the air moisture carrying capacity is improved; the waste liquid after heat exchange with the flue gas is pumped into a spraying layer 8 through a feedliquid circulating pump 4.

The combustion tail gas discharge pipe 2 is immersed 500-1000 mm below the liquid level of the waste water.

The diameter of a hole groove formed in the surface of the combustion tail gas discharge pipe 2 is 2-8 mm, and the effluent gas velocity is 1-3.5 m/s.

The spray chamber is positioned above the main structure of the normal-pressure low-temperature evaporation concentration equipment, the side surface of the bottom of the spray chamber is provided with an air inlet, and the direction of an air outlet is upward along the spray chamber; room temperature air enters from the side surface of the bottom of the spray chamber under the action of an air blower and is blown from bottom to top; the feedliquid circulating pump 4 circulates the wastewater in the evaporation chamber, the circulating wastewater is sprayed out through a spraying layer arranged above the spraying chamber, and is in reverse contact with air from top to bottom to transfer heat, the air absorbs heat and is heated, the moisture carrying capacity is increased, and the saturated wet air takes away the moisture in the feed liquid and is discharged along aflue gas pipeline 10 above the spraying chamber; the spraying layer is provided with two or more stages to enhance the gas-liquid contact heat transfer effect and improve the evaporation concentration efficiency of the system.

The upper part of the spraying layer in the spraying chamber is provided with a steam-water separation device, such as a demister, and various forms such as a silk screen, a folded plate and the like can be adopted. The top flue gas pipeline is provided with exhaust gas adsorption equipment, adopts as adsorbing material such as active carbon, macromolecule resin, zeolite, gets rid of harmful gas composition in the flue gas, like ammonia, the waste water escape's that the burning produced VOCs etc. and the flue gas can purify, satisfies emission standard.

The operation temperature is 80-100 ℃ under normal pressure, and the method is suitable for the evaporation and concentration process of the thermosensitive feed liquid; the evaporation chamber and the spray chamber can use low-grade materials, such as glass fiber reinforced plastics and the like. The whole equipment is corrosion resistant, the anti-scaling capability is strong, the operation is stable, and the service life is long.

The utility model has the advantages that:

the utility model discloses a reduce equipment operating temperature and change heat transfer interface, under the low temperature condition, greatly increased scaling ion salting out's supersaturation further improves the concentrated multiplying power of feed liquid and effectively restricts the production of scale deposit and corruption simultaneously. Without a fixed heat transfer interface, the chance of scale formation adhering to the metal surface is also reduced, thereby mitigating equipment fouling and corrosion phenomena. The combustion evaporation technology and the air carrying wet evaporation technology can realize the process of low-temperature evaporation concentration under the normal pressure condition. The combustion evaporation adopts an immersion type, a fixed heat transfer surface is not arranged, the combustion evaporation directly contacts with the concentrated solution for heat exchange, and organic and inorganic scales are not generated on the inner wall of the evaporator. Meanwhile, due to the fact that non-condensation gas is generated by combustion, the boiling temperature of the waste water is 10-20 ℃ lower than that of the waste water under the atmospheric pressure. The air carries moisture to evaporate, and is similar to water evaporation and rainfall circulation in a natural gas phase system based on the principle that the water content in the air increases along with the temperature rise. The operation temperature is generally 70-90 ℃, moisture is carried by gas-liquid direct contact heat exchange, no fixed metal heat exchange surface is provided, and the scaling and corrosion risks of process equipment are reduced.

The utility model discloses a contain salt waste water and evaporate to the required concentration of technology or until appearing the crystallization salt under the ordinary pressure low temperature condition, reach nearly zero release and handle the requirement. The salt-containing wastewater is pretreated and then pumped into a normal-pressure low-temperature evaporation and concentration system, and the system is coupled with combustion evaporation and air-carrying wet evaporation technologies, so that the wastewater liquid is efficiently concentrated under the normal-pressure low-temperature condition. The flue gas discharged by the normal-pressure low-temperature evaporation and concentration main body equipment contains combustion tail gas, water vapor, moisture-carrying air, entrained entrainment, volatile gas in waste water and the like. The flue gas is respectively subjected to steam-water separation and flue gas purification devices to remove substances such as entrained liquid water and harmful gases, and then is cooled by a condensing heat exchanger to obtain condensed water for further recycling. Meanwhile, the clean smoke is discharged after reaching the standard. The normal-pressure low-temperature evaporation concentration main body equipment is provided with a feed liquid circulating spraying device, and waste water in the system is continuously circulated and evaporated to reach the concentration ratio of the process requirement and then is discharged out of the system.

Drawings

Fig. 1 is a process flow diagram of the present invention.

FIG. 2 is the schematic structural diagram of the normal pressure low temperature evaporation concentration equipment for salt-containing wastewater of the present invention.

In the figure: 1-an evaporation chamber; 2-a combustion exhaust gas discharge pipe; 3-a burner; 4-feed liquid circulating pump; 5-a blower; 6-an air inlet pump; 7-a spray chamber; 8-spraying layer; 9-a demister; 10-flue gas duct; 11-a waste gas adsorption unit; 12-saline wastewater feed pump; 13-condensing heat exchanger.

Detailed Description

The present invention will be further described with reference to the accompanying drawings and examples.

The first embodiment.

As shown in fig. 1.

The salt-containing wastewater after pretreatment in the salt-containing wastewater evaporation concentration process enters normal-pressure low-temperature evaporation concentration equipment, generated flue gas enters a condensation heat exchanger after steam-water separation and flue gas purification treatment, obtained condensed water is recycled, purified flue gas reaches the standard and is discharged outside, and feed wastewater is discharged out of a system after reaching a specified concentration ratio through a cyclic evaporation process; the normal-pressure low-temperature evaporation concentration equipment is provided with a fuel gas and air supply pipeline; fuel gas and part of air are used as energy input of a combustor, and the generated high-temperature flue gas heats feed liquid and is evaporated to obtain secondary steam; part of the air is used as a water vapor carrier, and a large amount of water in the wastewater is carried away in the temperature rising process; the feed wastewater and the clean flue gas discharged by the system pass through a condensing heat exchanger to realize preheating and enter the evaporation concentration equipment from the upper part of the normal-pressure low-temperature evaporation concentration equipment so as to improve the energy efficiency of the system; the discharged concentrated solution of the evaporation concentration equipment can be continuously crystallized and desalted according to the process requirements, so that the salt of the wastewater is recycled.

The salt-containing wastewater comprises various salt-containing wastewater generated in the industries of fine chemical industry, coal chemical industry, natural gas collection and processing, garbage disposal and the like. The method can be directly discharged salt-containing wastewater in the process, or the salt-containing wastewater after pretreatment and membrane pre-concentration unit treatment. The salt-containing wastewater can enter the normal-pressure low-temperature evaporation concentration system after being operated by a proper pretreatment unit. The specific pretreatment process can be determined according to the water quality conditions of different salt-containing wastewater, basically, flocculation, sedimentation and filtration units are required to be arranged, impurities such as suspended matters, particles, colloids and the like in the wastewater are removed, and the stable operation of the fluid delivery pump is ensured. Meanwhile, the blockage and the failure of the spraying device are avoided. If the hardness and alkalinity of the feed wastewater are high, a two-alkali method (sodium hydroxide and sodium carbonate) dosing system can be arranged to remove scale forming ions such as calcium, magnesium ions and carbonate ions. If the concentration of organic matters in the feed wastewater is higher, a biochemical treatment unit can be arranged, the content of organic matters in the feed saline wastewater is reduced, the scale of tail-end flue gas purification treatment can be reduced, and the recycling efficiency of salt in the concentrated solution is improved.

One path of the pretreated salt-containing wastewater enters a spray chamber at the upper part of the evaporation concentration equipment from a circulating spray device through a condensation heat exchanger, and the other path of the pretreated salt-containing wastewater directly enters an evaporation chamber at the lower part of the evaporation concentration equipment. The evaporation chamber is provided with a combustor and a combustion tail gas discharge pipe, the discharge pipe is immersed in waste water, and the depth is 500-1000 mm. The surface of the discharge pipe is provided with a hole groove as a high-temperature flue gas discharge port, the diameter is 2-8 mm, and the effluent gas velocity is 1-3.5 m/s. The combustor is preferably a low-nitrogen type combustor, the combustion chamber is provided with an ignition hole, and an electric spark ignition device is adopted. And is provided with fuel gas and air conveying pipelines as the energy input of the combustor. The fuel gas is ignited and burnt in the air to generate a large amount of high-temperature flue gas, the high-temperature flue gas enters the waste water in a bubble form through the discharge pipe, the high-temperature flue gas is directly contacted with the gas and the liquid to transfer heat, the heat is transferred to the waste water, the waste water absorbs the heat, the temperature rises to the boiling point to generate a large amount of secondary steam, and the feed liquid is concentrated. The cooled flue gas and the generated secondary steam are discharged from the upper part of the evaporation chamber and enter a spray chamber. The spray chamber is provided with a plurality of stages of spray layers, and the feed liquid is uniformly sprayed downwards by a circulating pump through a spraying device. The spraying layer is provided with an atomizing nozzle for atomizing the feed liquid into liquid drops with smaller particle size. The side face of the bottom of the spray chamber is provided with an air inlet, and the direction of the air outlet is upward along the spray chamber. Room temperature air enters from the bottom side of the spray chamber under the action of the blower. The atomized liquid drops sprayed downwards are directly contacted with air, smoke and secondary steam which go upwards for heat exchange, the temperature of the air is increased, the moisture carrying capacity of the air is increased, the moisture in the liquid drops is further reduced, the liquid drops fall into an evaporation chamber below, and the feed liquid in the evaporation chamber is further concentrated. The wet air, the combustion tail gas and the secondary steam continue to flow upwards to the top flue gas pipeline, and if volatile substances such as ammonia or VOCs and the like exist in the waste water, the volatile substances are also dissipated and flow upwards to the flue gas pipeline through the processes of spraying, gas-liquid contact and heat transfer. The upper part of the spraying layer is provided with a steam-water separation device, such as a demister, and various forms such as a wire mesh, a folded plate and the like can be used. So that liquid drops entrained in the gas which goes up to the flue gas pipeline can be intercepted and removed.

The gas entering the flue gas pipeline contains VOCs possibly generated in the combustion process and VOCs and other harmful gases dissipated in the evaporation process of the salt-containing wastewater, and the VOCs and other harmful gases are removed through an adsorption device arranged in the flue. According to the specific VOCs components and harmful gas properties, proper adsorbing materials are selected, such as activated carbon, macromolecular resin, zeolite and the like. And (3) the clean flue gas without harmful gas components enters a condensation heat exchanger along a flue gas pipeline, the temperature of the clean flue gas is reduced to 30-50 ℃, the wet air and the secondary steam are condensed to form liquid water, the liquid water is recycled, and the rest of the flue gas meets the emission standard and is discharged to the atmosphere from the inside and the outside of the system. The feed wastewater absorbs the heat of clean flue gas, the temperature rises to 60-80 ℃, and the feed liquid enters the evaporation concentration equipment from the circulating spraying system after being preheated to carry out the normal-pressure low-temperature evaporation concentration process.

Under the combined action of submerged combustion evaporation and air moisture-carrying evaporation, the feed liquid is continuously evaporated and concentrated, and when the concentration multiplying power required by the process is reached, high-concentration salt-containing wastewater is discharged out of the system and enters the next process unit. Generally, under the guidance of the concepts of zero-liquid discharge of wastewater and resource utilization of salt, discharged concentrated liquid continuously enters a crystallization device, and precipitated crystal salt is recycled. If the salt-containing wastewater has high organic content, harmful components and complex salt composition, has no recyclable value or has high recycling cost, the wastewater can be directly evaporated and concentrated to high concentration and then sent out for disposal as hazardous waste.

Example two.

As shown in fig. 2.

An energy-saving evaporation concentration device for salt-containing wastewater comprises a salt-containing wastewater feeding pump 12, a condensing heat exchanger 13 and a normal-pressure low-temperature evaporation concentration device, wherein the pretreated salt-containing wastewater is pumped into the condensing heat exchanger 13 through one path of the salt-containing wastewater feeding pump 12 and then is sent into a spraying layer 8 on the upper part of the normal-pressure low-temperature evaporation concentration device, the other path of the pretreated salt-containing wastewater enters an evaporation chamber 1 of the normal-pressure low-temperature evaporation concentration device, the condensing heat exchanger 13 and the normal-pressure low-temperature evaporation concentration device are communicated through a flue gas pipeline 10, the spraying layer 8 is positioned in the flue gas pipeline 10, a demister 9 and a waste gas adsorption device 11 are arranged in the flue gas pipeline 10 and on the upper part of the spraying layer 8, the main structure of the normal-pressure low-temperature evaporation concentration device consists of the evaporation chamber 1 and a spraying chamber 7, a burner 3 is arranged in the evaporation chamber 1 and is provided with a combustion tail gas discharge pipe 2, and the combustion tail gas discharge pipe 2 is immersed in the position 500-1000 mm below the surface of the wastewater, the surface of the combustion tail gas discharge pipe 2 is provided with a hole groove serving as a high-temperature flue gas discharge port, the diameter of the hole groove is 2-8 mm, and the effluent gas velocity is 1-3.5 m/s. The high-temperature flue gas directly contacts with the wastewater liquid for heat exchange, and the wastewater is heated until secondary steam is generated; the temperature of the flue gas is reduced, the flue gas leaves the evaporation chamber along with the generated secondary steam, and the flue gas upwards enters the spraying chamber 7 to perform secondary heat exchange with the waste liquid sprayed out of the spraying layer 8 and the air blown in by the air blower, so that the air moisture carrying capacity is improved; the waste liquid after heat exchange with the flue gas is pumped into a spraying layer 8 through a feedliquid circulating pump 4. The spray chamber is positioned above the main structure of the normal-pressure low-temperature evaporation concentration equipment, the side surface of the bottom of the spray chamber is provided with an air inlet, and the direction of an air outlet is upward along the spray chamber; room temperature air enters from the side surface of the bottom of the spray chamber under the action of an air blower and is blown from bottom to top; the feedliquid circulating pump 4 circulates the wastewater in the evaporation chamber, the circulating wastewater is sprayed out through a spraying layer arranged above the spraying chamber, and is in reverse contact with air from top to bottom to transfer heat, the air absorbs heat and is heated, the moisture carrying capacity is increased, and the saturated wet air takes away the moisture in the feed liquid and is discharged along aflue gas pipeline 10 above the spraying chamber; the spraying layer is provided with two or more stages to enhance the gas-liquid contact heat transfer effect and improve the evaporation concentration efficiency of the system. The upper part of the spraying layer in the spraying chamber is provided with a steam-water separation device, such as a demister, and various forms such as a silk screen, a folded plate and the like can be adopted. The top flue gas pipeline is provided with exhaust gas adsorption equipment, adopts as adsorbing material such as active carbon, macromolecule resin, zeolite, gets rid of harmful gas composition in the flue gas, like ammonia, the waste water escape's that the burning produced VOCs etc. and the flue gas can purify, satisfies emission standard. The energy-saving evaporation concentration process and the equipment for salt-containing wastewater of the utility model have the operating temperature of 80-100 ℃ under normal pressure, and are suitable for the evaporation concentration process of heat-sensitive feed liquid; the evaporation chamber and the spray chamber can use low-grade materials, such as glass fiber reinforced plastics and the like. The whole equipment is corrosion resistant, the anti-scaling capability is strong, the operation is stable, and the service life is long.

Taking the example of a large amount of leachate generated by a garbage incineration plant as further illustration, the leachate generated by the garbage incineration plant is generally concentrated by a membrane method, and then the amount of the leachate is about 150t/d, wherein COD is_crThe content is 5000-6000 mg/L, BOD₅1500-2000 mg/L of ammonia nitrogen, 70-90 mg/L of ammonia nitrogen, 60000-70000 mg/L of total soluble solid, 200-400 mg/L of suspended matter and total hardness (as CaCO)₃Calculated) 4000-5000 mg/L.

The salt-containing organic waste liquid firstly enters a two-alkali dosing pretreatment unit, sodium hydroxide and sodium carbonate medicaments are added into the waste water to remove a large amount of hardness ions such as calcium, magnesium and the like in the waste water, then a coagulant and a flocculating agent are added, and the reaction precipitated inorganic salt and impurities such as suspended matters, particles, colloids and the like in the waste water are removed through operations such as flocculation, precipitation, filtration and the like. Meanwhile, chromophoric groups contained in part of the wastewater are removed to a certain extent, and the organic matter content of the wastewater is reduced. Flocculation and sedimentation operations are realized by arranging a high-density sedimentation tank, and filtration operations are realized by arranging a plate-and-frame filter press. The pretreated waste water enters normal-pressure low-temperature evaporation concentration equipment, the waste water is input into a system through a feed pump, one path of the waste water is directly pumped into an evaporation chamber, and the input amount is adjusted to keep the waste water liquid level in the evaporation chamber constant. The other path enters a feed liquid circulating pipeline after being preheated by a condensing heat exchanger.

The main evaporation and concentration equipment consists of an upper spray chamber and a lower evaporation chamber, and is made of temperature-resistant glass fiber reinforced plastics. The inside combustor subassembly that is provided with of evaporating chamber adopts the low nitrogen type, and the combustion chamber is equipped with the ignition hole, adopts electric spark ignition. The bottom of the combustion chamber is connected with a combustion tail gas discharge pipe, the surface of the pipe is provided with a hole groove with the diameter of 6mm, high-temperature flue gas is discharged from a hole groove opening, and the effluent gas velocity is about 2 m/s. The combustion chamber is connected with a fuel gas and an air conveying pipeline, the fuel gas uses methane resources generated and collected by stacking garbage, and air required by combustion is blown in by an air blower. Considering the problem of standard emission of combustion tail gas, the biogas is pretreated by desulfurization and the like in advance to remove harmful impurity components. The biogas and air are ignited and combusted in the combustion chamber, the generated high-temperature combustion tail gas enters the waste water in the evaporation chamber in the form of bubbles through a discharge pipe, and the discharge pipe is arranged at the position 800mm below the liquid level of the waste water. The bubbles directly contact with the waste water for heat exchange, the high-temperature flue gas heats the waste water, the waste water is heated to generate a large amount of secondary steam, and the secondary steam and the combustion tail gas move upwards to the spray chamber together. The side surface of the bottom of the spray chamber is provided with an air inlet, and room temperature air is blown by an air blower and goes upwards along the spray chamber. High-temperature wastewater after evaporation and concentration in the combustion chamber is sprayed into the system through the multi-stage spraying layer arranged above the spraying chamber by the circulating pump. The spraying layer is provided with an atomizing nozzle for atomizing the wastewater into liquid drops with smaller particle size.

In the spray chamber, the upward gas comprises secondary steam from the evaporation chamber, combustion tail gas, blown air and downward gas comprises tiny liquid drops sprayed out from the spray layer. The ascending gas directly contacts with the descending liquid drops for heat exchange, the air temperature rises, the moisture carrying capacity is increased, and the micro liquid drops further realize the concentration process. Because the percolate concentrated solution wastewater contains ammonia nitrogen and volatile gas, the percolate concentrated solution wastewater can escape in the processes of wastewater evaporation and spraying and can go upwards to a flue gas pipeline along with combustion tail gas, secondary steam and moisture-carrying air. Before the ascending gas enters the flue gas pipeline, liquid drops carried by the gas are removed through a folded plate demister arranged above the spraying layer. The gas which goes up to the flue gas pipeline is removed with harmful gas components such as ammonia gas and the like through an adsorption device arranged in the pipeline, and the adsorption device is filled with active carbon adsorption materials. And (3) the purified flue gas after the harmful gas components are removed enters a condensation heat exchanger to exchange heat with the wastewater feeding material, the wastewater absorbs heat and is heated to 70-75 ℃, the purified flue gas releases heat and is cooled to 45-50 ℃, secondary steam in the purified flue gas and water vapor in the moisture-carrying air are condensed into liquid water to be recycled, and the residual purified flue gas reaches the standard and is discharged to the atmosphere.

And continuously evaporating and concentrating the waste water in the evaporation chamber, conveying the generated residual distillation liquid to a solid-liquid separation system through a lifting pump for dehydration treatment, continuously refluxing the supernatant liquid to evaporation and concentration equipment, and regularly collecting and treating finally formed residues and salt mud.

The utility model discloses the part that does not relate to all is the same with prior art or can adopt prior art to realize.

Claims (5)

1. The utility model provides an energy-conserving evaporation concentration equipment of salt waste water, it includes contains salt waste water charge pump (12), condensation heat exchanger (13) and ordinary pressure low temperature evaporation concentration equipment, contain salt waste water after the preliminary treatment and pump into condensation heat exchanger (13) through containing salt waste water charge pump (12) all the way and then send into spraying layer (8) on ordinary pressure low temperature evaporation concentration equipment upper portion, in another way gets into evaporation chamber (1) of ordinary pressure low temperature evaporation concentration equipment, be linked together through flue gas pipeline (10) between condensation heat exchanger (13) and the ordinary pressure low temperature evaporation concentration equipment, spraying layer (8) be located flue gas pipeline (10), in flue gas pipeline (10), spray the upper portion on layer (8) and install defroster (9) and waste gas adsorption device (11), characterized by ordinary pressure low temperature evaporation concentration equipment major structure constitute by evaporation chamber (1) and spray chamber (7), the evaporator (1) is internally provided with a burner (3) and is provided with a combustion tail gas discharge pipe (2), the combustion tail gas discharge pipe (2) is immersed in waste water, and the surface of the combustion tail gas discharge pipe (2) is provided with a hole groove as a high-temperature smoke discharge port.

2. The energy-saving evaporation and concentration equipment for saline wastewater as claimed in claim 1, wherein the combustion tail gas discharge pipe (2) is immersed 500-1000 mm below the wastewater liquid surface.

3. The energy-saving evaporation and concentration equipment for salt-containing wastewater as claimed in claim 1, wherein the diameter of the hole groove formed on the surface of the combustion tail gas discharge pipe (2) is 2-8 mm, and the velocity of the effluent gas is 1-3.5 m/s.

4. The energy-saving evaporation and concentration equipment for salt-containing wastewater as claimed in claim 1, wherein the spray chamber is located above the main structure of the normal-pressure low-temperature evaporation and concentration equipment, the side surface of the bottom of the spray chamber is provided with an air inlet, and the direction of the air outlet is upward along the spray chamber; room temperature air enters from the side surface of the bottom of the spray chamber under the action of an air blower and is blown from bottom to top; the spraying layer is provided with two or more stages to enhance the gas-liquid contact heat transfer effect and improve the evaporation concentration efficiency of the system.

5. The energy-saving evaporation and concentration equipment for salt-containing wastewater as claimed in claim 1, wherein a steam-water separation device is arranged at the upper part of the spraying layer in the spraying chamber, and a waste gas adsorption device is arranged on the upper flue gas pipeline to remove harmful gas components in the flue gas.

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