NL8102591A - METHOD FOR COOLING SECONDARY COOLING WATER IN A POWER PLANT AND COLUMN SYSTEM TO BE USED THEREIN - Google Patents

Description

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Short designation: Method for cooling secondary cooling water in a power station and column system to be used for this.

The invention relates to a method for cooling secondary cooling water in a power plant according to the dry-wet process. The invention further relates to a column system for cooling secondary cooling water in a power plant, according to a dry-wet synergistic system. In particular, the invention relates to secondary cooling systems in thermoelectric or nuclear installations for generating electric energy.

In such systems, the steam from the turbine is cooled and condensed in a cooler, then returned to a primary circuit. The cooling and condensing is accomplished with a cooling liquid, generally water, in a secondary circuit. The cooling water must then be cooled and although dry cooling columns or cooling towers can be used for this purpose, so-called wet columns are used, whereby a lot of cooling water is used. This causes problems when installing power stations, which must be installed at a short distance from water sources. On the other hand, at least nuclear power stations should be located at a reasonable distance from the built environment, which is usually located near water sources. This causes problems with the supply of water at power stations due to the requirements for the water supply.

25 There are systems or installations where dry columns are combined with wet columns. These systems have been used industrially and the following results have been obtained: lowering the temperature of the cooling water brought to the temperature near the condensation temperature (wet bulb temperature), decreasing the required amount of water compared to the wet cooling columns, reducing the visible influence, namely the emission of water vapor (emission of the saturated air) and reducing the objections related to the environment.

According to a first approach to such systems, both the dry and wet columns are of almost equal structure, the dry column being arranged above the wet column and both being parallel 81 02 59 1 * i '-u -2- 219 ^ 1 / Uk / rab positioned relative to the surrounding air that is passed through it.

These columns are referred to as "integrated columns" (Marley, Ecodyne, Westinghouse). In the superposed dry column, the water to be cooled is fed into finned heat exchanger tubes, while in the wet column below, the water is distributed in the form of rain in the applied packing and the final adiabatic cooling is undergoing. A fan suitable for this purpose draws in the air from both towers or columns, remixes it and mixes it. discharge in an unsaturated state to the atmosphere. A drawback here is that the cooling water always comes into contact with the wet column, also in winter, and as a result of this, this does not provide suitable accommodation without a total drying of the two columns. Another drawback is that the adjustment of the temperature of the cool water is effected by valves, preferably arranged on the wet column, which valves must be very large. Variations in this system are possible with different relative placements between the wet and dry parts, but the drawbacks mentioned are not removed,

A second approach to the dry wet column system is to supply water which is directly sprayed onto the fins of the dry column (dry spray or Deluge columns). The heat is transferred from the cooling water flowing into the finned tubes * to the water to the fins and from there to the air as a mixture of sensible and latent heat. This column type has been widely used in Russia and Hungary, but presents a number of problems with regard to the fins and probably also with regard to the corrosion of the fins, depending on the chemical contamination of the sprayed water.

Another type of dry-wet column system was designed by Hudson 30 Products Corporation and provides a dry column and a wet column that only cooperate during a more or less short period where the ambient temperature has peaks of summer temperature. In this system, the heat to be dissipated is distributed between the two separate columns based on the minimum amount of water to be supplied available to the wet column during the summer operation.

Each column of the system is provided with its own egg screen, each column having its own part of the conventional double-walled cooling surface. The thermal or heat load is distributed between the two columns 81-2 5 91 I * -3- 21941 / Vk / rab ί * and the two columns operate at full load under the intended conditions. When the ambient temperature drops below the design temperature, the dry column increases the cooling capacity whereby the cooling section draws in a larger amount of steam to be condensed from the cooling section in the wet column. This system has the disadvantage that large investments are required in the wet column while it is not used for 10 months of the year or longer depending on the metereological conditions and the design of the particular installation.

One of the objects of the method and system of the invention is to achieve efficient cooling with a minimum amount of water used here and to overcome the drawbacks of the known systems.

The new method of cooling the water from the secondary cooling circuit in a power plant is characterized in that the secondary cooling water from a closed-circuit cooler is passed through a cooling zone with ambient air and then a cooling zone with humidified ambient air.

The color system for cooling secondary cooling water in a power plant according to a dry-wet synergistic system is characterized in that the secondary cooling water forms a closed circuit and the circuit consists of at least a first part where it can be cooled with ambient air in a cooling tower and a second part after the first part in which it is possible to cool in a cooling tower with humidified air.

The new method thus provides for cooling of the water from the secondary cooling system in a power plant by first passing the water through one or more ambient air-cooled heat exchangers and then through one or more heat exchangers operating with humidified ambient air.

The system according to the invention provides a secondary cooling circuit and in combination therewith at least one ambient air heat exchanger or a dry heat exchanger (hereinafter referred to as a dry column) and a humidified ambient air heat exchanger (hereinafter referred to as a wet column or wet heat exchanger ), which are cascaded so that the secondary cooling water flowing from the turbine cooler is first passed through an ambient air heat exchanger and then through the ambient air humidified heat exchanger. Preferably 81 02 5 9 1 * -it- 219 * n / Vk / mb, the units are composed of modular ambient air heat exchangers and modular ambient air heat exchangers.

In the new system, the cooling water from the secondary circuit is conducted in a closed cycle and thus no special treatments are required after the first feeding or filling operation with regard to the possible chemical agents that need to be controlled, which agents can be detrimental to the metals that come into contact with the cooling water. The water which serves to humidify the air for the wet heat exchanger does not need to undergo any special treatments when it is supplied to the circuit other than to humidify the air. For this purpose, the water can also be sea water.

Other important advantages of the system are the following.

The two-component system can be physically separated, for example by arranging it so that the heat exchanger with the humidified ambient air is arranged under the dry heat exchanger with the aim that the air from the first heat exchanger is not recirculated by the last heat exchanger .

The amount of water to be supplied is minimal and reduced to the short summer period.

At a certain temperature for the ambient air, humidification is no longer necessary and the heat exchanger with the humidified air works in the same way as the heat exchanger with the surrounding air.

At a certain temperature of the ambient air and at a certain discharge pressure of the turbine, the fan for the heat exchanger of the humidified air can be stopped and used as such.

It is possible to use inexpensive carbon-containing steel or other less expensive material with the tubes for the heat exchanger and the cooling plates.

Because the cooling water is in a closed cycle, it is always pure and has a higher film coefficient (higher heat exchange rate) in both the air-cooled heat exchanger and the cooler.

It is possible to use anti-freeze agents if required.

It is not necessary to use shut-off valves or "lowers" to control the airflow.

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No water vapor plumes are discharged into the environment through the heat exchanger with the humidified air, because the air is only saturated or nearly saturated before it is passed through the bundle of heat exchanger tubes and then only humidifies during the very short summer time.

The risk of freezing is eliminated when the heat exchanger is filled with humidified air.

At a nuclear power plant, the risk of the possible radiation hazard from the towers is no longer present.

The invention will be further elucidated on the basis of the following description, with reference being made to the appended drawing, in which: fig. 1 schematically represents the system according to the invention and fig. 2-4 are schematic modular forms of the equipment 15 used in the system.

In Fig. 1, 11 denotes the turbine for a power plant. The steam discharged therefrom is indicated by arrows 12 and is fed into a cooler 14 with the hot condensate source 16 which is discharged therefrom and recirculated by the condensate pump 18. A secondary cooling circuit, indicated in its entirety by 20 , provides for cooling the steam in the condenser or cooler. The stream of dust in the secondary cooling circuit, generally water, is introduced cold in the cooler through the supply pipe 22 and discharged in the heated state through pipe 24 (see the direction of the arrows). The cooling water is present in a closed circuit and is circulated by means of a recirculation pump 26.

In the secondary or air-cooled circuit 20, there is schematically shown a dry tower 30 (or ambient air heat exchanger) and a wet tower 40 (or humidified ambient air heat exchanger), 30 where columns 30 and 40 will be apparent in larger numbers than is indicated in the drawing, depending on the further requirements imposed on the design.

The dry column 30, which may be of any type, generally has a structure in which the secondary cooling water is passed through 35 finned tubes, schematically indicated at 32, while the outside air is passed over the recovered tubes according to the arrows 33 using one or more fan units 34.

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The tower 40 includes a structure where the secondary cooling water is passed through the finned tubes, schematically indicated by 42, while the ambient air is passed over the finned tubes, according to arrows 43, using one or more fan-5. units 43. The air drawn in from the environment is passed through the humidification zone 45 (in the drawing in two parts on two sides). In these zones, the water for humidification is supplied at 46 in the form of drops such as rain on grids or other objects for humidifying the ambient air.

TO The humidified water is supplied to a circuit 50 and pumped using a circulation pump 52, the water being discharged from a collection vessel 54 after zone 45 of column 40. The water is brought to the desired conditions at 56 before circuit 50. This can be done with fresh water supplied to the system and this is. 15 reasonably limited because it only has to replace the water that evaporates from the tower 50 and is carried by the air. This column or equipment 40 may operate with dry air or moist air depending on the ambient conditions and the conditions with which the secondary cooling water arrives at this location. Particularly because the column 30 with dry ambient air is always situated in front of (upstream) column 40, the use of humidifying water in this column 40 depends on the conditions of the secondary cooling water from column 30 and finally on the conditions of the ambient air. In particular, the system will only use humidifying water during the peaks of the summer temperature of the ambient air. Humidification will be terminated at a certain well-defined dry bulb temperature. Below this temperature, the heat exchanger with the humidified ambient air, which is when dry, will operate in the same way as the heat exchanger of the ambient air. It should be noted here that the temperature of the ambient air can be determined as the temperature at which the humidified air blower can be inserted into the heat exchanger. This lower temperature of the ambient air can be determined and set, for example on the basis of the determined pressure in the discharge of the turbine. It will be clear that the described system is particularly suitable to be used together with a known type of a turbine, in particular the 320 MW turbine with a discharge pressure of up to 17.5 cm Hg and then blocked outside this pressure .

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Preferably, according to an aspect of the invention, the dry column will be used in combination with wet columns in modules, consisting of a number of dry columns and a number of wet columns, preferably 5 columns or towers as a whole. Examples of such modules are shown in Figures 2, 3 and 4. Figure 2 schematically shows a module consisting of 4 columns 30 operating on ambient air, which are coupled in parallel to each other and for a column 40 which on humidified ambient air. Fig. 4 shows a module consisting of 2 columns 30 which are connected in parallel to each other and placed in front of 3 columns 40. Of course other modules are also possible.

-CONCLUSIONS- 81 02 5 9 1

Claims (9)

Method for cooling secondary cooling water in a power plant according to the dry-wet process, characterized in that the secondary cooling water from a closed circuit cooler is passed through a cooling zone with ambient air and then a cooling zone with humidified ambient air. 2. Column system for cooling secondary cooling water in a power plant, according to a dry-wet synergistic system, characterized in that the secondary cooling water forms a closed circuit and the circuit consists of at least a first part where it can be used. cooled with ambient air in a cooling tower and a second part after the first part in which it is possible to cool with a cooling tower with humidified air. System as claimed in claim 2, characterized in that the first column is connected to an ambient air supply, an air ventilation unit and finned pipes for the passage of the secondary cooling water, cooperating with the supply of the ambient air in the structure. System according to claim 2, characterized in that the cooling tower operating with humidified ambient air consists of a supporting structure with openings for the ambient air, a ventilation unit for propelling the ambient air and zones to which humidifying water is supplied. between the air vents and the ventilation unit, finned tubes for the passage of the secondary cooling water, means for controlling the supply of the humidifying water depending on the conditions of the ambient air supplied to the column and the secondary cooling water to be cooled. System according to claim 2, characterized in that the system comprises a number of modules, in which towers with ambient air are combined with towers with humidified ambient air, System according to claim 5, characterized in that a module consists of 4 ambient air towers arranged in front (upstream) and parallel to each other, and a humidified air tower after the ambient air towers. System according to claim 2, characterized in that the module 35 consists of 3 ambient air towers arranged parallel to each other and for 2 towers with humidified ambient air which are hereafter 81 02 5 9 1 -9-2 21941 / Vk / mb placed. System according to claim 2, characterized in that the module consists of 2 ambient air towers placed first and parallel to each other and 3 humidified ambient air towers placed 5 thereafter, System according to claim 2, characterized in that the module consists of 1 ambient air tower placed first and 4 humidified air tower placed next and arranged parallel to each other. Eindhoven, May 1981. 81 02 5 9 1