DE2430711A1 - Evaporation of water or aqs solutions - to make boiler feed water using steam produced by cooling a blast furnace for heating - Google Patents

Abstract

Liquid, in particular water or aqueous solns., is distilled using steam generated during the cooling of a blast furnace as heating medium. After at least partial condensation this steam is returned to the blast furnace cooling system. The blast furnace cooling can continue even when the still is not working. The prodn. of distillate continues when the furnace stops. The still works under optimal conditions independent of the variations in steam flow from the furnace. A still can be designed to match a new installation even though the steam flow from the furnace cannot be accurately predicted.

Description

Device for heating distillation systems for distillation of water and aqueous solutions The invention relates to a device for heating of distillation systems for the distillation of water and aqueous solutions, whereby water vapor serves as an energy carrier.

Distillation devices for the production of drinking water from sea water have long been known in shipping (Chemiker-Zeitung / Chemische Apparatur 88 year 1964, No. 12, page 433). They are either with the exhaust steam from the turbines or operated with the waste heat from the diesel engines that are used to propel ships.

These are small systems with only one evaporation stage in some cases. From a procedural point of view, they can be controlled easily and without complications.

Distillation devices, however, only work under certain conditions, respectively specified operating conditions (DAS 1 808 985). These are from the Temperature of the heating medium, the working pressure Ü.a. depending on what the evaporation rate the liquid to be reprocessed is determined. This rate of evaporation largely determined for their part. the quality of the distillate.

It is also known (DAS 1 274 043) to keep the Amount of steam to be supplied to a distillation device with fluctuating turbine output and thus if the amount of steam in the distillation volume changes additional supply of steam.

It is also known in the large-scale production of Drinking water from seawater uses the waste heat from nuclear reactors that are used in power plants serve to generate electricity (nuclear technology, 7th year, 1965, p. 289ff, chemical engineering, 41st year, 1969, p. 103).

The steam generated with the heat of the nuclear reactors is used for turbines the electricity generation supplied.

The exhaust steam from these turbines is then used to heat a distillation plant used the i. a.

is based on the principle of flash distillation. This is Although an economical production of drinking water is possible, it does occur Considerable problems arise due to the fact that, as already mentioned, distillation plants must generally be operated with constant amounts of steam. For this reason the steam turbine and the distillation plant are designed so that both with one specified total output. If the total energy requirement is not reached of the entire system, for example by the fact that there is a lower demand for electricity, water vapor from the steam boiler is fed directly to the distillation system, there a reduction in steam consumption in distillation plants is fundamentally not possible is possible. Further difficulties arise from the fact that electrical current fluctuations occur very quickly, and a regulation of the steam consumption of the distillation plant cannot be customized.

Such procedural difficulties arise in principle in all large systems that are used for Desalination or processing of wastewater and for drinking water supply from seawater, with the individual Some of the reasons have not yet been explored. In addition, the partial pressures of the individual evaporation stages must not deviate too much from one another, since otherwise water hammer and damage to the heat exchangers will occur.

It is also already known to make drinking water from sea water using solar energy to create. These procedural problems do not arise because the Water evaporates from shallow pools and condenses on colder surfaces. The one here The problems that arise are more physical in nature and have led to an industrial scale Drinking water is not possible.

A proposal that is not yet part of the state of the art provides as a heat source for the operation of evaporation systems, those discharged as steam To use waste heat from blast furnaces. Apart from the fact that this is new technical territory is entered, there is also the fact that when a blast furnace is built, the The amount of steam cannot be calculated in advance. After commissioning there are deviations of up to 70%, i.e. the amount of steam produced depends on the calculated in advance can be higher or lower by the same order of magnitude. The reasons for these strong deviations have largely not yet been explored. One influence on the amount of steam produced appears to be, among other things, the lining of the blast furnace to lie.

As a result of these difficulties or the as yet unknown influences has despite the long-term need for heat sources for distillation systems experts have not considered the use of waste heat from blast furnaces, rather, when using nuclear reactors, he took the one that can never be completely ruled out Risk of a nuclear accident in purchase.

The invention is based on that which does not yet belong to the prior art Proposal from the waste heat from blast furnaces for the operation of distillation plants to use. You have the task of creating a device that it enables the operation of distillation plants intended in the planning of blast furnaces, these operating data of the blast furnace, which can only be determined in advance in terms of magnitude To take into account.

According to the invention, this object is achieved by one with the steam chamber connected to the distillation plant and with the water cooling of a blast furnace generated steam and one independent of the blast furnace Additional line for the supply of one of the actual value-setpoint deviation of the steam quantity of the blast furnace corresponding additional amount of steam.

This measure ensures that the theoretical Prediction of the amount of steam Recalling can be borne because - as already mentioned -a distillation plant to operate satisfactorily for a given and essentially constant steam throughput of heating steam must be designed.

In addition, it is achieved that the for a certain to be produced Water volume designed distillation plant independent of individual fluctuations the amount of steam supplied by the blast furnace can be supplied.

On the sliding side, it is possible to use the distillation systems via the additional line to start, or in the event of failure of the blast furnace, what a rapid decline the steam supply has the consequence of shutting down or continuing the distillation system to operate without damage such as caused by the sudden failure of the steam supply the already mentioned water hammer and the like occur.

To determine this amount of steam that deviates from the actual value setpoint blindly according to the invention in the steam supply line and in the additional line, respectively a quantity measurement (pressure and temperature corrected) arranged.

Since the steam of the plant network is under a higher pressure than the The steam emitted by the cooling of the blast furnace is, in a further embodiment, the Invention in the additional line a pressure reducing valve with downstream condensate injection arranged.

In yet another embodiment of the invention is in the steam supply line and one in the line for the condensed water vapor Shut-off element arranged so that if the blast furnace fails, its cooling circuit can be separated from the distillation plant and this only via the plant network will continue to be operated.

According to the invention, it is advantageously between the shut-off element a container in the line for the return of the condensate and the blast furnace arranged, from which the condensed water vapor continuously cools the blast furnace is fed back.

This condensate container is a further embodiment of the invention Can be connected to the consumer by means of shut-off devices, so that in the event of operation, that the distillation plant is via the plant network as well as with blast furnace steam is operated, excess condensate or distillate formed in the steam chamber is given to the consumer.

In yet another embodiment of the invention, the section the line for the return of the condensed water vapor between the shut-off element and the steam chamber via a further shut-off device with a distillation vessel connectable. This measure ensures that when the Distillation plant with the steam of the factory fresh water that is formed in the steam chamber Condensate of this shut-off device is led into the stillation tank, whereby the shut-off device in the line for the return of the condensate to the blast furnace is blocked.

In the event that the distillation system only uses the steam of the blast furnace is operated, is in yet another embodiment of the invention a shut-off device is arranged in the additional line.

In the event that the distillation plant is in operation during operation of the blast furnace fails, an emergency capacitor is required to ensure adequate cooling of the blast furnace provided, which can be connected to the distillation vessel via shut-off devices. . In this trap, the steam from the blast furnace transfers its heat to the emergency condenser and flows back to the blast furnace via the distillation tank Another circuit allows a distillation column to be used as an ionc'ensator.

Further advantages and features of the invention are given in the appendix of a preferred one From the exemplary embodiment explained in more detail in the drawing.

In the drawing, the first-- distillation column 1 is a multi-stage one Distillation system shown schematically, which in a known manner with is connected to the other distillation columns.

It is used in the present case to contaminate River water to be processed so that it can be used for in-house listening purposes can.

This distillation column consists of the evaporator 2, its collecting tank 3 to the river water to be desalinated via a line 4 'and the heat exchanger 4 is supplied. This river water with a not shown is from the collecting tank Pump is pumped to the top of the evaporator and through nozzles 5 in the evaporator sprayed. Concentric to the evaporator is arranged in the steam chamber 6, which with the steam supply line 7 of the blast furnace, not shown, and with the line 8 is connected for the removal of the condensate that has accumulated in the steam chamber.

This water vapor introduced into the steam chamber gives off with condensation its heat, which is to be desalinated essentially as radiant heat from the sprayed River water is supplied.

As a result, part of the sprayed river water goes into the vapor phase, enters the line 9 and then into the heat exchanger 4. In this condenses part of the steam and flows via line 10 into the distillation vessel 11 and from this via a valve 19 to a consumer, not shown. This can be, for example, a cold rolling mill.

The steam that is not condensed in the heat exchanger 4 passes through the Line 12 into the next distillation column, not shown.

In line 7 for the supply of the steam produced by the blast furnace a measuring orifice 13 is arranged, behind which a shut-off device in the direction of flow 14, e.g., a shut-off valve is arranged. The line 8 for the return of the Condensate formed in the steam chamber leads via a shut-off device 20 to a Condensate tank.

This is with the cooling device of the blast furnace over the line 16 and a pump, not shown, connected. This line 16 is via a Valve 17 with the line 18 of the distillation vessel leading to the consumer 11 connected, which also has a valve designated 19. From the pipe section the line 8 between the shut-off element 20 and the steam chamber leads via a shut-off element 21 a line 22 to the line 10.

From the portion of the line 7 between the valve 14 and the Steam chamber leads the line 23 to the additional line 24, on the one hand via a Pressure reducing valve 25, a measuring orifice 26 and a shut-off element 27 with the one not shown Works network and on the other hand via the shut-off valve 28, the emergency capacitor 29 and the valve 30 is connected to the line 10.

In the ideal operating state, the blast furnace is used for production a predetermined amount of distillate required amount of steam supplied to the steam chamber 6.

This condenses, flows into the condensate container 15 and from here back to the furnace. Valves 14 and 20 are in this operating state opened and valves 21, 17, 27 and 28 closed.

If too much water vapor is condensed in the steam chamber 6, will the excess amount is discharged via the valve 17, which is then to be opened. This is then the case when the blast furnace supplies too little steam and additionally from the plant network Steam is fed in, The throughput of the water vapor given off by the blast furnace cooling is monitored by means of the measuring orifice 13.

The distillate obtained from the contaminated river water is how already mentioned, fed to the distillate tank 11.

If the amount of steam supplied by the blast furnace is used to generate a specified amount of purified river water per hour designed distillation plant is not sufficient, the amount corresponding to the difference between the actual value and the setpoint is used Water vapor is supplied from the plant network via line 24 23. Since normally the plant network is under a higher pressure than the steam from the blast furnace, is in the pressure reducing valve 25 is provided for the additional line. In this operating state the valves 27, 21 are also open. As a result, steam comes from the plant network Via line 23 into the steam chamber, there is at least some of its heat of vaporization from, condenses and passes through the open valves 20 and 21 into the condensate or distillate tank.

However, if the blast furnace fails, the distillation plant will only shut down operated via the plant network.

For this purpose the valves 14 and 20 are closed. same for also for starting or

Shut down the distillation system in order to carry out the operations described at the beginning Avoid water hammer and damage.

If the distillation plant fails, it must be ensured that the blast furnace is cooled is ensured.

For this purpose, the further supply of steam from the plant network is through Closing of the valve 27 prevented and the valves 28 and 50 and 19 and 17 opened. As a result, the heat is released in the emergency capacitor 29 or in a Distillation column with corresponding switching of the pipe network.

The measures according to the invention ensure that at Disturbances or failure of the distillation plant ensured the cooling of the blast furnace is, and that on the other hand, if the blast furnace fails, the production of distillate for the Production facilities continued and damage to the distillation plant avoided will. In stationary operation it is also ensured that the distillation plant under optimal conditions, regardless of fluctuations in the steam supply to the blast furnace or the works network is working. The measures according to the invention ensure that that even in the planning of new systems the essentially unknown operating situation n can be taken into account by blast furnaces.

Expectations

Claims (9)

Claims 1. Device for heating distillation systems for the distillation of water and aqueous solutions, using water vapor as an energy source serves, characterized by a connected to the steam chamber of the distillation plant and the steam supply line fed by the steam produced during the water cooling of a blast furnace (7) and an additional line independent of the blast furnace for the supply of an additional one Steam amount that corresponds to the actual value-setpoint deviation of the steam amount of the blast furnace. 2. Apparatus according to claim 1, characterized by one, each flow meters arranged in the steam supply line and in the additional line (13 or 27) to determine the actual value-Sollüert deviation. 3. Apparatus according to claim 1 or 2, characterized by an in the additional line arranged pressure reducing valve (25). 4. Apparatus according to claim k, 2 or 3, characterized by each one in the steam supply line (7) and one in the line for the return of the KonEnsat arranged shut-off devices (20 or 21). 5. Apparatus according to claim 4, characterized by an between the shut-off device (20) arranged in the line for the return and the blast furnace Condensate container (15). 6. Apparatus according to claim 5, characterized in that the condensate container Can be connected to the distillate container via a shut-off element (17). 7. Device according to one or more of the preceding claims. characterized in that the section of the line for the return between the 2 # bsperrorgan and the steam chamber via a shut-off element (21) with the distillate tank (11) is connectable. S. Device according to one or more of claims 1 to 7, characterized by a shut-off element (27) arranged on the additional line. 9. Apparatus according to claim 8, characterized by an emergency capacitor (29), which can be connected to the distillate container (11) via shut-off devices (28 or 30) is.