JPH0921503A - Plant for heating and deaerating supply water - Google Patents

Abstract

PROBLEM TO BE SOLVED: To reduce the cost of a feed water tank by employing a direct contact type feed water heater as a feed water heater in a system of a type wherein the feed water heater is disposed between a condenser and a feed water tank and is connected to a steam turbine by a steam extraction tube. SOLUTION: A pump 7 having a five stage structure feeds water to a feed water heater 1 by a first stage pump thereof through a feed water tube 19. The water fed through the feed water tube 19 is injected into the feed water heater 1 by means of an injecting device 1a and collides with extracted steam from a low pressure turbine ND in a doomed region of the feed water heater 1. Water which has heated condensed steam is collected in a bottom portion of the feed water heater 1 and sent to a second stage of the five stage pump 7 and the water in the feed water heater 1 is sent to a feed water heater 2. Steam extracted from the low pressure turbine ND is sufficient for the feed water heater 2, 3. Feed water heaters 4, 5 are supplied with steam extracted from a medium pressure turbine MD. The water and the extracted steam directly contact with each other so that the extracted steam is efficiently utilized for heating the feed water until the extracted steam is condensed.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a plant for heating and deaerating feed water by steam, which mainly comprises a plurality of feed water heaters connected in series on the water side. Relating to the type in which the condenser is arranged between the condenser and the water tank and is further connected to the steam turbine by an extraction pipe

[0002]

2. Description of the Prior Art Plants for heating and degassing feed water of the type mentioned at the outset are known. For example, in a general-purpose steam power plant, water is delivered by a main condensate pump from a condenser through multiple, eg, four, low pressure feedwater heaters to a direct contact feedwater heater with a deaerator. . Here, so-called surface contact feed water heaters are used in the four feed water heating stages. A feature of surface contact feed water heating is that all the water to be heated is sent through a pipe, which is surrounded by a tank.
The bleed air from the turbine is sent into the tank, and this bleed air is
It flows through the outer wall of the pipe and condenses while producing heat.

The extracted bleed air is supplied to the water circuit by a condensate pump. The final feed water heating stage constitutes a direct contact feed water heater for deaeration, in which the bleed air and the water to be heated are in direct contact. In this arrangement, the residual subcooling of the water is overcome and the bleed air is completely reconstituted with the exception of a small part, at the same time the gas constituents in the water are eliminated by known means.

In the surface contact type feed water heater, the water pressure in the pipe and the extraction air pressure in the tank are different from each other. That is, the structure of the tank with the safety device must be based on a dual pressure system.

In the conventional steam power plants described above, the steam required for heating is usually extracted from a low pressure turbine for the first three surface contact feedwater heaters. With this arrangement, a relatively high quality bleed air must be used for each feedwater heating stage. High quality steam must be extracted from the medium pressure turbine for heating in the last surface contact feed water heater and the subsequent direct contact feed water heater with degassing. Such steam is meant to improve the efficiency of the steam process during further expansion in the turbine. Moreover, the amount of bleed energy in the surface contact feed water heater cannot be used efficiently for feed water heating. This is reflected in the so-called final temperature difference. The final temperature difference is defined as the temperature difference between the condensate temperature of the bleed air and the heated water flowing out of the surface contact feed water heater. For these surface contact feed water heaters, the final temperature difference is typically about 3K (Kelvin). In other words, undesired energy losses occur here. This is because the energy amount of extraction air for heating the feed water is not fully utilized.

That is, the heating of the feed water by the surface contact feed water heater has a complicated structure, and the cost for the structure and maintenance of the tank is high. Furthermore, it is necessary to reduce the final temperature difference that occurs during heating of the feed water and use the energy of the extracted air more efficiently.

[0007]

The object of the present invention is to improve a plant of the type mentioned at the outset so that the water required in terms of pressure and temperature when feedwater heating takes place in tanks of simple construction. It is an object of the present invention to provide a plant for heating and deaerating feed water so as to maintain the above condition and at the same time improve the utilization efficiency of extraction energy.

[0008]

In order to solve this problem, in the structure of the present invention, the feed water heater is a direct contact feed water heater.

[0009]

An advantage of the present invention is that, in particular, the use of direct-contact feedwater heaters known per se in series-connected circuits saves costs on the construction of the tank.

A more efficient use of the energy of the bleed air in a direct contact feed water heater is particularly advantageous as a final temperature difference of 0K (zero Kelvin) is achieved. That is,
The water supply heating of water is performed by the amount of energy that can be efficiently used for extraction. Thus, maintaining the water requirements and reducing the demand for high quality steam, especially from the high pressure turbine.

In this plant for heating and deaerating feed water, the individual condensate pumps for supplying water to the direct contact feed water heaters arranged in series are arranged on a common shaft and are connected in common. It is particularly advantageous to have a drive of

An embodiment of the invention for incorporation in a power plant is shown schematically in the drawings.

[0013]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of the present invention will be described in detail below with reference to the drawings.

Reference numeral MD in the drawing denotes a medium-pressure turbine of a general-purpose steam power plant, and ND denotes a low-pressure turbine of a general-purpose steam power plant. On the outflow side, the exhaust pipe 13 connects the low-pressure turbine ND to the condenser 9. Condensate supplied from the condenser 9 to the pump 7 via the condensate pipe 10 is conveyed by the pump 7 to the direct contact feed water heater 1. This direct contact feedwater heater 1 is a feedwater heater known per se and fulfills the functions of feedwater heating for steam processes and degassing of water. Here, the direct contact feed water heater 1 is part of a plant for feed water heating and water degassing. The whole plant mainly consists of five direct contact feed water heaters 1, 2, 3, 4, 5 connected in series. All direct contact feed water heaters 1, 2, 3,
4 and 5 have the same function. These known functions will first be described by way of example with respect to the first direct contact feedwater heater 1. The function of this feed water heater 1 is
The direct contact feed water heaters 2, 3, 4, 5 are also filled in the same manner. Below, a series of circuits of direct contact feed water heaters 1, 2, 3, 4, 5 with special advantages will be explained in detail.

As mentioned above, the pump 7, which here forms a five-stage structure, is arranged in the first pump stage in the control valve 1
Water is supplied to the direct contact type water supply / water absorption heater 1 through a water supply pipe 19 provided with 2. The water level in the condenser 9 is adjusted by the control valve 12. The direct contact feed water heater 1 has a vertical cylindrical central part, which is closed by a dome at the top and at the bottom, respectively. The water supplied by the water supply pipe 19 is supplied to the injection device 1
It is injected from above into the direct contact feed water heater 1 by a. This water collides with the bleed air from the low pressure turbine ND in the dome area at the top of the direct contact feed water heater 1.
This bleed air is fed directly to the feed water heater 1 via the bleed pipe 14.
Sent in. The water is heated when the energy of the steam is released, whereas the steam itself condenses and mixes with the water. The heated water containing condensed steam is collected at the bottom of the direct contact feed water heater 1. When mixing and heating water with steam, the non-condensable gas dissolved in the water is separated from the water. These gases are discharged in the dome area at the top of the direct contact feed water heater 1 by the degassing pipe 1b.
At this end, the degassing pipe 1 is connected to the low pressure region of the condenser 9 via the degassing pipe 11. The water supply pipe 1c sends the water collected at the bottom of the direct contact feed water heater 1 to the second stage of the five-stage pump 7. The pump 7 sends the water whose water level has been adjusted by the direct contact feed water heater 1 to the direct contact feed water heater 2 which is the next feed water heating stage. This direct contact feed water heater 2 and subsequent direct contact feed water heaters 3, 4, 5
Also works in the same manner as the direct contact feed water heater 1. There is a difference in the quality of steam required for successive feedwater heating steps. As the temperature of the preheated water increases step by step, higher quality steam must be fed to the direct contact feed water heater from one feed water heating stage to the next.
Low pressure turbine N for direct contact feed water heaters 2 and 3
The extraction of steam from D is sufficient, whereas the direct contact feed water heaters 4, 5 are supplied with bleed air from the medium pressure turbine MD.

The fifth or final feed water heating stage differs in other respects. Here, the direct contact feed water heater 5 is open at the bottom and is arranged directly on the feed tank 6. The water tank 6 collects heated water containing condensed steam.

The pump 7 used in this plant is 5
It consists of two pump stages, which are arranged on one shaft and have a common drive 8.

The advantages of feed water heating in a series of circuits of a direct contact feed water heater are as follows.

The direct contact feed water heaters 1, 2, 3, 4, 5 for heating feed water and degassing the water used in the plant described are mainly of relatively simple construction and thus inexpensive. It consists of a large tank, in which water and steam come into direct contact at the same pressure. That is, the direct contact feed water heaters 1, 2, 3, 4, 5 are single pressure devices.

-By direct contact between water and bleed air,
The energy content of the bleed air is effectively utilized for heating the feed water until the bleed air is reconstituted, in which case the mixture of heated water and condensed bleed air is at the same temperature. Therefore, the above-mentioned final temperature difference is 0 here.

The above-mentioned most effective use of the energy content of the bleed air for heating the feed water is the comparison of the bleed air from the high pressure turbine under the same conditions required for the steam process of the water state with respect to pressure and water temperature. It means a very small demand. By saving bleed air from the high pressure turbine stage in this way,
The heat consumption in the steam process is reduced and at the same time the thermal efficiency is improved. Therefore, the aforementioned plant for heating feed water and degassing improves thermal efficiency by approximately 0.3%.
The use of direct contact feed water heaters not only provides a cheaper feed water heating plant, but also significantly improves the overall efficiency of the steam power plant.

Of course, the invention is not limited to the embodiments described above. Thus, for example, a series connection combining a surface contact feed water heater and at least two direct contact feed water heaters is also feasible within the scope of the invention. The number of direct contact feed water heaters used is also not limited to five and can be varied in relation to the process.

[Brief description of drawings]

FIG. 1 shows a plant for feed water heating and water degassing for use in a general purpose steam power plant.

[Explanation of symbols]

1-5 direct contact type feed water heater, 1a-5a spraying device, 1b-5b deaeration pipe, 1c water supply pipe, 6 water tank, 7 pump, 8 drive device, 9 condenser, 10 condensate pipe, 11 deaeration pipe, 12 Control valve, 13 Exhaust pipe, 14-18 Extraction pipe, 19-
23 Water pipe

Claims (6)

[Claims] 1. A plant for heating and degassing feed water with steam, which mainly comprises a plurality of feed water heaters connected in series on the water side, the feed water heater being a condenser. In the type which is arranged between (9) and the water tank (6) and is further connected to the steam turbine (ND, MD) by the extraction pipes (14, 15, 16, 17, 18), The feed water heater is a direct contact feed water heater (1, 2, 3, 4,
5) A plant for heating and deaerating feed water, characterized in that 2. The five direct contact feed water heaters (1,
2, 3, 4, 5) are connected in series on the water side, the first three direct contact feedwater heaters are connected on the steam side to a low pressure turbine (ND), the fourth and fifth. 2. The plant for heating and deaerating feed water according to claim 1, wherein the direct contact feed water heater of claim 1 is coupled on the steam side to a medium pressure steam turbine (MD). 3. The plant for heating and degassing feed water according to claim 1, wherein the last direct contact feed water heater (5) is arranged on the feed tank. 4. A pump (7) is arranged upstream of each direct contact type feed water heater on the water side, and a water supply pipe (19, 20, 21, 22, 23) is assigned to each pump (7). And, the water supply pipe is a direct contact type water supply heater (1, 2, 3,
4, 5) spraying devices (1a, 2a, 3a, 4a, 5)
The plant for heating and degassing feedwater according to claim 1, which has reached a). 5. The water supply pipe (19, 20, 21, 22, 22)
5. Plant for heating and degassing feed water according to claim 4, wherein the pump (7) coupled to 23) is arranged on one shaft and has a common drive (8). 6. The direct contact feed water heater (1, 2,
Degassing pipes (1b, 2b, 3b, 4) where 3, 4, 5) are gathered in a common degassing pipe (11) connected to the condenser (9)
Plant for heating and degassing feedwater according to claim 1, which is connected to b, 5b).