HU201997B - Dry cooling tower of natural draft - Google Patents

Abstract

Dry-cooling tower using natural draught for cooling warm water without evaporation, the ribbed coolers (5) which assist the flow of warm water being arranged horizontally, and the coolers being assigned adjustable louvres, which control the intensity of the cooling, and a heater unit (14) which blows in warm air serving the purpose of preheating. According to the invention, the louvres (13) in the cooling tower (1) are likewise arranged in the horizontal plane above the air coolers (2). <IMAGE>

Description

The present invention relates to a natural draft dry cooling tower.

Dry cooling towers are called industrial or crockery equipment that cools hot cooling water in air coolers without evaporation and discharges waste heat into the environment.

For the sake of size, a 200 MW crown unit - which can now be considered a medium power unit for dry cooling - has the following parameters:

- heat to be withdrawn 300 MW

- cooling water flow 7 m ³ / s

- tower height 120 m

- bottom diameter llOm

- ribbed air cooling area 600 000 m ²

air cooler weight 6001

With these sizes, the natural draft is economical. The draft and the airflow it generates almost immediately as hot water enters the air cooler.

Movable or adjustable shutters, such as those described in U.S. Pat. No. 4,397,793, are often used in dry cooling towers. document, where the damper provides airflow variation and thus control power.

Air flow louvers are commonly used in both ventilator and natural draft cooling towers. This solution for controlling the heat sink is used for two common types of cooling towers.

The first type is the traditional "Hcller" cooling towers, which are characterized by the fact that the air coolers are mounted side by side along the lower circumference of the tower and that the water flows vertically in the pipes while the cooling air flows horizontally into the tower. . The shutters are installed in front of the radiators. This solution was advantageous, among other things, because the shutters, especially in the closed position, provided perfect protection against the air coolers behind them, either from damage or dirt.

Another common solution is the so-called. use of column-like air coolers. These are characterized by the fact that the air coolers are arranged horizontally inside the tower. The air coolers can be mounted either radially or parallel to each other. Again, the air flow louvers are located on the air inlet side of the air coolers, which means that they are located under the air coolers.

Both of the above-mentioned known solutions are suitable for controlling the mass flow of air through the air coolers, and thus the power of the air coolers, and to isolate the out-of-service air coolers on the side.

Dry cooling tower operators are well aware of the problem of operating in full cold, and especially during frost-dangerous start-ups. A variety of solutions have been developed by designers to preheat the air coolers prior to heating the air with water.

The known solution for preheating air coolers, implemented on Hellcr towers, is that the solution is to blast warm air through smaller air handling units and lower air coolers between the stationary coolers and the front control louvers flowing through the air coolers, they slowly warm up. The device itself also contains a water-cooled air cooler, but its size is much smaller, its pipes are shorter, so starting and filling it is not a danger. It is easy to see, and experience has shown that preheating in this way requires very high cooling power and a significant airflow, as the hot air leaving the air coolers is discharged through the tower chimney and is thus lost.

As for the lost heat, it should be noted that the cooling tower releases very large amounts of heat to the environment. In such cases, there are no specific control problems, and tasks can be solved simply by formatting.

However, there are two problems:

- when the cooling tower is started up, when the technology to be cooled does not produce large enough heat, the water system is filled with heavily cooled water. Of course, the freezing of the water system can easily occur.

- Frequent fracture problems can occur during repeated operation of an air cooler group after disconnection - especially due to its large size, the air cooler surface is divided into groups that operate in parallel. they are broken during maintenance. Re-commissioning these is just like a startup problem, like the problem of starting an entire cooling tower.

The adjustable or movable shutters used in dry cooling towers, which allow the air flow to change and the power to be controlled, reduce the air flow inside the tower to such an extent that there is no significant draft, despite inevitable gaps. The warm air passing through the gaps cannot fill its entire cross-section, and the local, upward air movement is counterbalanced by the flow of cold air flowing in the opposite direction from the top of the tower.

A large number of parallel water pipes are located in the air coolers. In the exemplary cooling tower, for example, water flows through about 30,000 pipes 17 mm in diameter, each 30 m in length. As mentioned above, unwanted water chill (freezing) can occur in the individual pipes or on a smaller or larger portion of the air cooling surface, which causes injury or malfunction in the pipes or air coolers. It will be appreciated that the cold metal weight 6001 mentioned in the example is capable of freezing a portion of the amount of water received during filling and closing the tubes with the resulting jcg plugs, causing frostbite. When draining, freezing may occur by draining water from some pipes too slowly and freezing the remainder of the water cooled by cold air.

For frost-free charging and emptying, it is customary to preheat cold air coolers, keep them warm, and choose a solution that stops the airflow through the air coolers during charging and emptying.

A common feature of known preheaters is that they direct the hot air to the outside of the air cooler, so that this hot air passes directly through the air cooler into the chimney of the cooling tower, meaning that this preheating air is largely useless

HU 201 997 Β lost. Tckintcibc Considering the exemplary geometric dimensions and performances, this wasted heat is extremely significant and very expensive.

Our aim is to design a natural draft dry cooling tower that allows the predominantly lost heated air to be recharged and discharged and used for continuous heating of the air coolers.

The invention is based on the discovery that when air coolers placed inside the cooling tower are used, the draft control shutters are installed not in front of the radiators but after the radiators such that the shutters are enclosed above the radiators in a structure similar to a diving bell. thus, the introduced preheater hot air can be captured, permanently used to preheat the air coolers and thus, when necessary, eliminate the need to use an external heat source to preheat the air coolers.

FIELD OF THE INVENTION The present invention relates to a natural draft dry cooling tower for cooling hot water evaporation units, in which the ribbed radiators for the flow of hot water are arranged horizontally; and that the chillers are associated with adjustable shutter louvres having a cooling intensity and a preheating heater blowing hot air. The novelty of the invention is that the shutters in the cooling tower are also mounted above the air coolers in the horizontal plane. The cooling tower further has an adjustable shutter located above the shutter in the cooling tower casing and / or a shutter located between the air coolers and the cooling tower chimney wall in the plane of the radiators, and / or having additional shutters which they are arranged in a horizontal plane below the plane of the radiators;

The preheating heater assembly may consist of a portion of the air coolers provided with a fan whose nozzle is provided in the space in front of the air coolers below the damper. Optionally, the heating unit is provided with a heat exchanger having an antifreeze fluid as a heat transfer medium in one of its branches. The heater can be connected to an external heat source. The heater can be equipped with automatic control via a temperature sensor.

The design of the natural draft dry cooling tower according to the invention provides the following advantages:

- when starting a cooling tower, when the technology to be cooled does not produce large amounts of heat and the water system is filled with heavily cooled water, the hot air introduced to preheat the radiators can be captured in the enclosed space around the radiators until the radiators become frost-free. In this way, much of the hot air blown to pre-heat the air coolers so far is not lost, and significant energy savings can be achieved.

- When re-commissioning an air cooler group after a cut-off, freeze can be eliminated by ensuring that the warm air stored in the space around the refrigeration unit provides adequate frost protection for the re-commissioned pipe sections without the need for additional hot air.

The arrangement of the invention makes it possible to dispense with the use of an external heat source as a heater unit, such as a part of the air coolers, which may also be used as a heater unit with a blower which blows the hot air under the air cooler.

An exemplary embodiment of a natural draft dry cooling tower according to the present invention will be described in greater detail by reference to the drawing, wherein:

Figure 1 illustrates a natural draft dry cooling tower according to the invention fitted with a shutter according to the invention,

Fig. 2 illustrates the arrangement of Fig. 1 with an additional shutter assembly arranged in the plane of the air coolers,

Figure 3 illustrates the cooling tower arrangement shown in Figure 1 with additional shutters arranged below the air coolers,

Fig. 4 illustrates the structural arrangement of Fig. 1, with the addition that the air cooler is equipped with a heat exchanger having an antifreeze fluid in one of its branches. This air cooling section serves as a heating unit.

The dry cooling tower shown in Fig. 1 is operated with natural draft in such a way that the air coolers 2 integrated in the cooling tower 1 cool the water coming from the conduit 3 by means of the air stream 10. The cooled water is discharged through the 4 conduits.

At start-up, valve 6,7, 8cc 9 is closed and no water is present in the air cooler 2. The water flows through the bypass valve 5. Above the air cooler 2, a shutter 13 is disposed, which at start-up is in a closed position, thereby forming a downward-opening "dive bell" -like space. The cooling tower casing 1 is fitted with 11 shutters which are open at start-up. If a draft is formed in the cooling tower 1, it is eliminated by stirring the cold air stream 12.

A portion of the air coolers form the heating unit 14, which is provided with a fan 15. After opening the valve 6, the heater unit 14 is put into operation. If the fan 15 is then started, the heater blows the hot air stream 16 into the space below the shutter 13. The hot air gradually fills this space and then returns to the inlet side of the heater 14 via the air cooler 2, whereby hot air is circulated.

When the preheating of the air cooler 2 is completed, which can be stopped, for example, by measuring the temperature of the metal surface, the valves 8 and 9 must be opened and the valve 5 closed. Then all the air coolers are put into operation and the water flows through them. After the filling, the shutter 11 must be closed and the shutter 13 opened as required by the cooling capacity.

The fan 15 stops when charging is complete. The heater 14 then operates in the same way as the air coolers 2.

When draining in cold weather, the shutter 13 must be closed first. At this point, the airflow 10 is substantially reduced. The shutter 11 must be opened and the remaining draft 12 will be closed by the cold air stream 12. The fan 15 must be started and the air coolers 2 must be dewatered, maintaining the flow of hot air 16. The heater 14 must be last dewatered after the fan 15 has been stopped.

THE 2. The solution shown in Figs. 1 to 4 is different in that the shutter 11 is not located on the cooling tower mantle but in the lower plane of the air coolers 2, inside the tower 1.

In extremely cold environments, the effect of the shutter 13 and 11 can be enhanced by an additional shutter 17 located beneath the air coolers 2. In this embodiment, shown in Figure 3, the horizontally positioned air coolers 2 are completely

EN 201 997 Β enclosure space, which the heating unit 14 can heat up in a short period of time.

For frost-free filling and emptying, it is desirable to make the hose assembly 14 of ribs having a larger diameter than usual, since increasing the diameter significantly reduces the frostbite.

In very cold environments, filling and emptying the heater formed from a large diameter spout can also cause problems. Emptying and stopping is more reliable if the heater is filled with antifreeze (eg oil or antifreeze). Figure 4 shows such a solution.

The flow between the hot and cold conduits 3 is started by opening the valve 5. The heat exchanger 18 has hot water flowing on one side and antifreeze fluid flowing on the other side. The latter 19 is circulated between the heat exchanger 18 and the heating unit 14 by a pump 19. When the heating is complete, the pump 19 stops.

The operation of the shutters can be automated. For example, valves 6, 7, 8 and 9 only open when shutter 13 is closed and shutter 11 is open. The shutter 11 closes when the filling is complete, as indicated, for example, by the fact that the valve 5 is closed.

When adjusting the shutters and the fan, keep in mind that preheating is of course only necessary in frost-prone times. It is advisable to equip the heating unit with automation known as a temperature sensor.

Claims (6)

PATENT CLAIMS A natural draft dry cooling tower for the evaporative cooling of hot water, in which the ribbed chillers for flowing mcleg water are arranged horizontally; The chillers are associated with adjustable chutes for controlling the cooling intensity and a preheating heater unit for supplying hot air, characterized in that the chutes (13) are also mounted horizontally above the chillers (2) in the cooling tower (1). The natural draft dry cooling tower according to claim 1, characterized in that the cooling tower (1) has an additional adjustable shutter (11) which is located above the shutters (13) in the mantle portion of the cooling tower (1) and / or further louvers (11) are arranged in the plane of the air coolers (2) between the air coolers (2) and the horn wall and / or in the horizontal plane below the plane of the air coolers (2) are further louvers (17). The natural draft cooling tower according to any one of claims 1 or 2, characterized in that the preheating heater unit (14) comprises a part of the air coolers (2) equipped with a fan (15) having a blower outlet (11). below the air coolers (2). 4. The natural draft dry cooling tower according to any one of claims 1 to 4, characterized in that the heating unit (14) has a heat exchanger (18) in which a heat transfer medium is provided with an antifreeze fluid. 5. The natural draft dry cooling tower according to any one of claims 1 to 3, characterized in that the heating unit (14) is connected to an external heat source. 6. The natural draft dry cooling tower according to any one of claims 1 to 3, characterized in that the heating unit (14) has automatic control by a temperature sensor.