DE2360491B1 - Industrial effluent purificn. - e.g. wash water from a dye works with recovery of salt-free sterile water - Google Patents

Abstract

Purification of industrial effluent, partic. the heavily polluted effluent arising in a part of a plant in which a heat consumer operating at >>100 degrees C is present, by (a) heating the effluent prior to its entry into an evaporator, to a temp. close to its b.pt. at such a pressure than when evaporated in a tube evaporator to give a vol. increase of 1000:1 it produces steam meeting the requirements of the heat user, (b) passing the resultant mixt. of steam and foam at high velocity into a separator, partic. a cyclone, (c) using the energy of the purified steam in the process, (d) recycling the condensed steam as process water and burning the concentrate, if desired with heat recovery. In particular, where volatile impurities are present the steam is passed through an adsorption and/or neutralisation filter.

Description

Here we see progress in two directions; once will eliminates the need to have to destroy energy, on the other hand the treated wastewater can be reused as service water in the company. Of the Technical progress of the invention can be seen in the fact that the evaporation from Wastewater with the other method has a superior cleaning effect in this way can be used for the first time with high economic efficiency.

Last but not least, there is an ingenuity in the structural design the apparatus that uses this process against the prejudices against evaporation allows under high pressures.

So far the opinion was that evaporation under high pressures for rapid contamination, yes, must lead to encrustation of the evaporator walls.

According to the invention, the evaporation of the waste water in tube evaporators completed, to which the wastewater is supplied heated up to the boiling point, so that the evaporation in the tubes spontaneously under an increase in volume of up to t: 1000 takes place, whereby the vapor with that produced during evaporation Foam flows through the tubes at such a high speed that not only does it become dirty or encrustation does not occur, but the tubes of the evaporator in this way be protected from deposits.

Due to the tangential entry of the steam foam mixture with high Speed in the separator completely destroys the foam and the liquid content the foam flows down the walls of the separator following gravity, where it is deposited. The steam is discharged through a dip tube in the steam dryer are arranged in a known construction, which is also based on the centrifugal principle work and drain the liquid.

It is advantageous to remove volatile substances contained in the steam by adsorption and / or remove the neutralization filter.

Industrial wastewater often contains oxygen carriers such as peroxide i.a. m., which at the claimed pressures and temperatures with the also oxidizable substances can lead to explosions. According to the invention in the separator and in the evaporator the absolute quantities of oxidizable substances by means of a level control kept so small that in the event of an ignition the possible pressure increase in the apparatus the device is not endangered.

The novelty of the invention, its technical progress and its Inventiveness is evident from the fact that in the publications the subject the invention is not included.

For example, B. German Offenlegungsschrift 1 767 483 probably on an evaporation process for emulsions for the separation of oil and water under atmospheric pressure and in negative pressure. That contained in the vapor of the last stage However, the heat of vaporization is not recovered, but in the amount that has been customary up to now Way destroyed by cooling.

The German Offenlegungsschrift 1 621 648 relates to a method for evaporation of rinsing water under atmospheric pressure at the at the Evaporation, as has been the norm up to now, for bath heating below 1000 C is used.

The German Offenlegungsschrift 2060387 relates to evaporation from domestic wastewater, also under atmospheric pressure and heat recovery for household heating with heat transfer media below 1000 C.

There is an embodiment of the invention that is very important in practice in that during evaporation the heat on the water by means of a fluid heat transfer medium is transferred, which can optionally also be fed directly into the heat consumer will can.

Together with the indirect heating of the heat consumer via a Namely, this opens up a control option that the Adaptation to the company, e.g. B. a plant in the textile industry, facilitated. the The heating of the heat consumer is no longer part of the continuous operation of the das Wastewater generating part of the plant bound, z. B. in a plant in the textile industry not to the continuous running of the washing device. This is achieved by that there are separate line circuits with heat transfer media from the high-pressure steam part are, of course, the heat transfer medium for heating the evaporator and that for the heating of the heat consumers are usefully the same. It So a part of the heat transfer medium can be removed from the evaporator and instead into the heat consumer. This is important because an industrial plant of the type in question mostly not in all parts of the plant works with constant performance. So it can happen that z. B. in a dyeing plant a lot is dyed and washed, so that in the There is no more wastewater from washing at the moment. At the same time, however, dryers, Continue working on coating systems etc. Without wastewater to be evaporated, however no superheated steam is generated to heat the dryers, coating systems, etc. Without special precautions, they could no longer continue their operations. Due to the presence of separate heating circuits from the superheated steam circuit However, it is now possible to use heat transfer media that would otherwise be used to heat the evaporator required heat transfer medium past this directly into the heat consumer to steer, so that they continue to operate even if there is no sewage can. The entire heat transfer medium flow can thereby be applied to the heat consumers be steered. This is the case when there is no wastewater at all. The evaporator is then practically shut down. All intermediate stages are also possible in which part of the heat transfer medium passed directly to the heat consumer Part of the operation of the evaporator is needed, which is the amount of water that just accumulates evaporates and the heat of the water vapor via the other heat transfer medium as well to the heat consumers. The other borderline case is when the the waste water generating part of the plant, so z. B. the washing machine, before. Here will then a large amount of superheated steam is generated, which is so much heat via the heat transfer medium can give that the heat consumers can be heated entirely in this way and nothing of the first heat transfer medium directly to the heat consumers, but everything goes into the evaporator.

In order to further increase the economic efficiency of the energy balance, some of the condensate heat of the evaporated wastewater can be transferred to the fresh wastewater be transferred before its evaporation.

In this way, the new wastewater can depending on before evaporation Amount to a temperature close to the evaporation temperature be preheated without energy having to be supplied from the outside.

The evaporation residues contain particularly in the textile industry often high proportions of organic material, which is combustible under suitable conditions is.

By burning off such evaporation residues can further energy can be usefully fed back into the energy balance.

The inventive method is advantageously a Recovered water that is both salt and germ-free.

Another object of the invention relates to a system for implementation of the method according to the invention, which is characterized in that with a An evaporator is connected to the cooler by a pipe via a heat exchanger, the one on its evaporation side via a line, a cyclone and a Line connected to the heat exchanger and behind it to a condenser is, while the part of the condenser containing the heat transfer oil is via a pump, a flow line and a return line with heat consumers in a first Heat cycle is connected and that on the other hand the evaporator to a second Heat circuit is connected to a heating system.

Advantageously, is in the system between the cyclone and a Control valve arranged a level regulator.

The drawing shows an exemplary embodiment in the form of a dyeing system represented by the textile industry.

In the washing machine 1, a large amount of heavily soiled falls Waste water, which is fed to a collecting tank 3 via a drain 2, the If desired, fresh water can also be added via an inflow 4. the end the waste water reaches the collecting tank 3 via a shut-off and non-return valve 5 in a pump 6, which brings the wastewater to a pressure of 30 atü. The sewage, which is still cold, then flows through a cooler 7, the purpose of which will be explained below will. Via the line 8, the wastewater then passes into a heat exchanger 9, in which it absorbs from the line 10 heat up to the boiling point. That now already preheated wastewater then enters the evaporator 11, where it is under the increased pressure up to 30 atü spontaneously with a volume increase of up to 1: 1000 is evaporated. A mixture of water vapor then passes through line 12 and foam attributed to the contaminants present in the wastewater is. This mixture enters the cyclone 13, in which it is in rapid rotation is displaced, whereby the heavier components under the action of centrifugal force apply to the walls and flow downwards, where they collect in line 14, the amount being determined by a level control 44. Via a valve 15, which maintains the pressure and prevents the steam from being blown out through line 14 is, the separated concentrate reaches the collecting container 16 without pressure which it is drawn off by the pump 17 of the oil burner 18 and then burned. the generated heat can be fed back into the cycle.

The steam freed from the impurities in this way emerges at the top of the cyclone through line 10, in which steam dryers are installed. He passes through the heat exchanger 9, in which it uses part of its thermal energy for preheating of the waste to be evaporated transfers water to this. Then the steam enters the condenser 19, in which it transfers most of its heat content to a heat transfer oil releases and condenses in the process. The condensation is completed in a condensation pot 20 The resulting warm water reaches the cooler 7 via line 21, where it is further cooled down by the inflowing cold wastewater. Via the valve 22 and the line 23 can then the water in the washing machine 1 and thus in the Water cycle can be returned.

In the condenser 19, the generated superheated steam transfers a substantial amount Part of its heat content in a heat transfer oil that is used to heat a dryer 24 and a coating system 25 is used. The heat transfer oil is made by the pump 26 circulated and arrives via a flow line 27 and branch lines 28 or 29 in the dryer 24 or the coating system 25. Each of these units is a control valve 30 is assigned, which via a temperature sensor 31 from a controller 32 is actuated. Depending on the in the dryer 24 or the coating system 25 The total amount of the supplied via the branch lines 28, 29 is the desired temperature Heat transfer oil passed through the dryer 24 or the coating system 25 or a subset via a bypass line 33 provided with a throttle 34 in a return line 35 fed back. The throttle 34 ensures that the pump 26 always approximately even with different NEN settings of the control valves 30 must work against the same resistance.

The evaporator 11 is not heated directly, but via a heat transfer oil that is heated in the heating system 36 and by the pump 37 is circulated. This heat transfer oil transfers the heat generated by the burner 38 on the evaporator dl, with the valve 39 a control option for the through the evaporator 11 directed amount of the heat transfer oil and thus the transferred to this Amount of heat is given.

The valve 40 has an important function, which allows the to to tap the evaporator 11 leading line 41 for the heat transfer oil and one Part or the total amount of the heat transfer oil heated in the heating system 36 Via the line 42 and the circulating pump 43 directly into the dryer 24 or

to manage the coating system 25. The dryer this way 24 or the coating system 25 supplied amounts of heat transfer oil are therefore directly through the heating system 36, not via the one generated in the evaporator 11 Superheated steam in the condenser 19 has been heated. From the line 10 can before Condenser 19, if necessary, removed steam for operational purposes in the usual way will.

The area of high pressure, i. H. the pressure generated by the pump 6 from 20 to 30 atmospheres, is limited to the part of the system, the lines with small Circles are provided. All other lines carry heat transfer oil or steam or Water at atmospheric pressure or, if necessary, slightly increased pressure for circulation.

Claims (1)

Claims: 1. Process for the purification of industrial wastewater, in which heavily contaminated wastewater occurs in one part of the plant and at least a heat consumer working at temperatures well over 1000 C is present is, d a d u r c h characterized that the wastewater is before entering a tube evaporator heated close to its boiling point under the pressure that ensures a steam, which meets the requirements of the heat consumer, it in the tube evaporator evaporated with a volume increase of up to 1: 1000, the tensioned steam with the Foam fractions created during the evaporation process at high speed leads into a separator that uses the energy of the cleaned steam in operation, the pure condensate of the steam is used again as process water and the concentrate if necessary burns with heat recovery 2. The method according to claim 1, characterized in that characterized in that, in the case of volatile substances, the steam is absorbed by adsorption and / or neutralization filter conducts 3. The method according to claim 1, characterized in that that you pass the steam through a separator, which works on the principle of a cyclone works, cleans and dries 4. The method according to claim 1, characterized in that that the concentration of ignitable substances in the separator can be controlled by a level control keeps it so small that in the event of ignition there is only an acceptable increase in pressure, which does not endanger the apparatus 5. Attachment for carrying out the process according to Claim 1, characterized in that with a cooler (7) through a line (8) via a heat exchanger (9) an evaporator (11) is connected, on the one hand on its evaporation side via a line (12), a cyclone (13) and a line (10) connected to the heat exchanger (9) and behind it to a condenser (19) is, while the part of the condenser (19) containing the heat transfer oil via a Pump (26), a flow line (27) and a return line (35) with heat consumers is connected in a first heat circuit and that on the other hand the evaporator (tt) connected to a second heat circuit with a heating system (36) is. Various ways are known to purify such wastewater. In an essentially mechanical type, the effluents are passed through clarifiers led, which sand and coke filters are upstream, the in the wastewater dissolved dye as well as various organic and inorganic dissolved in water Absorb salts. There are also seepage basins in operation through which the water in the Soil seeps away and from time to time it is cleaned of the sewage sludge that has been retained will. In another type of wastewater treatment, those contained in wastewater are removed Colloids (fiber breakdown products, dyes, carbohydrates, fats, soaps) on chemical Paths failed There are processes of catalytic oxidation and ion exchange used, processes of the forced osmosis and, last but not least, processes of the biological Wastewater treatment. All of these processes do not meet the requirements of the industry The biological wastewater treatment probably shows a sufficient one for municipal wastewater Suitability, but also cannot be used for the recovery of industrial water will. All the types of wastewater treatment mentioned have in common that they do not provide any thorough cleaning of the wastewater and still residues of chemicals get into the watercourses and the groundwater, so that they have recently Considerably increased requirements from the point of view of environmental protection will no longer be sufficient in the long run. The process with the best separating effect for foreign substances dissolved in the water, namely evaporation, has so far hardly been considered for wastewater treatment, because the heat requirement for the evaporation of the water is extraordinarily high. The resulting water vapor of atmospheric pressure and about 1000C can in any case in the given large amounts are not used, so that the contained therein Energy is lost and so far the energy costs for this type of wastewater treatment were way too high. For this reason, evaporation plants have been designed for the various purposes in such a way that one with multi-stage systems lower energy consumption aspired and the evaporation pulled down as far as possible into the vacuum, so that at generally reduced energy level of the evaporation process a destruction of the Thermal energy contained in the vapor of the last evaporation stage by means of a cooler water or in refrigeration companies. This corresponds to the current state of the technique. The method according to the invention takes a completely new approach, in that, in contrast to the current state of the art, the evaporation under considerably increased energy makes, so the energy expended minus the less Losses in the generated steam are reused in heat consumers can be. The invention therefore provides a method for purifying Industrial wastewater in which one part of the plant contains heavily contaminated wastewater and at least one working at temperatures well above 1000 C. Heat consumer is present, which is characterized in that the wastewater before entering a tube evaporator close to its boiling point under that pressure heated, which ensures a steam that meets the requirements of the heat consumer corresponds to it in the tube evaporator with a volume increase of up to 1: 1000 evaporates, the tensioned steam with the foam components created during the evaporation process leads at high speed into a separator, the energy of the cleaned Steam used in operation, the pure condensate of the steam as service water again begins and the concentrate burns, possibly generating heat.