RU2313729C2 - Excess air system with tubular air heater - Google Patents

Abstract

FIELD: power engineering, possibly development and reconstruction of boiler units.

SUBSTANCE: in excess air system provided with multi-way tubular air heater having air recirculating line at least with one air-water heat exchanger, air take-up to recirculating line is realized from split between ways of air heater. Recirculating line is connected through bridge having shutter with outlet of last way of air heater and with draining unit.

EFFECT: enhanced efficiency of excess air system provided with multi-way tubular air heaters arranged after economizer along gas motion direction.

5 dwg

Description

The invention relates to energy, in particular to the air path systems of steam generators (boilers), containing devices - heat exchangers for taking heat from flue gases in the area of multi-pass tubular air heaters, which are located in the flues of steam generators (boilers), can be used in thermal power plants.

Airway systems are known in which heat exchangers are located both on the air recirculation line connected to the outlet of the last stroke of the air heater through the air, and in the cut between its moves [1, 2, 3, 4].

So, at the 800 MW unit, there is an excess air system (Fig. 1, 2) with an air-water heat exchanger for heating network water, which is located on the air recirculation line connected to the hot air supply line to the furnace from the last stroke of the air heater and to the supply line air in its first turn [1, 2, 3]. There is also an additional recirculating air line bypassing the heat exchanger, and a line for discharging hot excess air into the atmosphere. A gate is installed on the recirculation line in front of the heat exchanger. This system is the closest claimed. After cooling in the heat exchanger, excess air taken from the hot air stream by the recirculating air fan is fed into the mixer, where it is mixed with the main air stream from the blower fan and enters the first stroke of the air heater, which is the outlet gas stream. The required temperature of the air inlet to the air _preheater - t ' _TVP - is provided by regulating the flow rate of the recirculated excess air bypassing the heat exchanger at a given heat exchanger heat removal - Q I / _O - and with the corresponding load of the recirculating air fan. The main cubes in the strokes (steps) of the air heater are made with the same pipe arrangement, mainly of the same size. To further increase the extraction of heat from flue gases by increasing the mass air velocity in all strokes of the air heater, a line for discharging excess air into the atmosphere is provided, connected to the outlet of hot air from the last stroke of the air heater.

An air path system is also known, in which an air-water heat exchanger is also placed between the air heater strokes — in a cut through the air — (FIG. 3). It can be used to heat mains water or bypass part of water heaters in a turbine regeneration system [3, 4].

At high temperatures of feed water and unfavorable ratios of water equivalents of flue gases and blast air, deep cooling of the flue gases in a boiler with a conventional thermal circuit is impossible [4]. A significant increase in the efficiency of a power unit is possible only by taking heat from a gas stream. Both systems: a heat exchanger in passages crosscuts between the air heater and air heat exchanger system with a recirculation line for excess air, can reduce the flue gas temperature - T _yi, and increase boiler efficiency - h _ka.

The disadvantage of these schemes is, however, an insufficient amount of heat taken from the flue gases in the area of the air heater. An insufficient decrease in the value of T _y due to the limited need for heat removal in heat exchangers, especially in the summer when using them for heat supply.

In the case of using heat exchangers for heating the bypasses of part of the water heaters in the turbine regeneration system, there is a decrease in the efficiency of the power unit due to the replacement of the heat of steam extraction from the turbine by the gas heat in the TVP region, although the turbogenerator power is increased.

In case of forced unloading of the fans of the recirculating air in the existing excess air system, in particular in the summer period, there will be a decrease in the heat transfer coefficient K _TVP in all strokes of the air heater and, accordingly, an increase in T _w .

So, at a power unit of 800 MW, where an excess air system is used, the value of T _yh at the base load significantly exceeds the design, reaching 180 ° C and higher, despite the temperature of the gases in front of the air heater - T ' _TVP (Fig. 1).

The objective of the invention is to increase the efficiency and economy of the excess air system.

To solve this problem, an excess air system is proposed with a multi-way tubular air heater equipped with an air recirculation line, at least one air-water heat exchanger, in which air is drawn into the recirculation line from the cut between the air heater strokes, while the recirculation line is connected by a jumper equipped with a gate with an exit from the last stroke of the air heater and with a reset.

Wherein:

- In the inventive system of excess air improves the ratio of water equivalents of the coolant along the course of the heater. Increasing pressure and temperature the mass increases air velocity through the 1st through the air (the end on gases) to move air preheater crosscuts with appropriate selections with a significant decrease in the values of T _yi under identical with the existing excess air system defined _vvto values Q and t _'TID. This increases the heat removal in the first stroke through the air of the air heater and in the air heater as a whole.

- In the inventive system of excess air, the flow rate of recirculated air when it is taken from the cut through the bypass of the heat exchanger will be greater than in the existing system with the same set values of Q _input and t ' _TVP . In this case, the value of T _Uh will additionally decrease.

- In the inventive system of excess air, discharging it into the atmosphere during selection from the cut with the aim of reducing T _uh contains significantly less heat lost than in the same discharge in the existing system, which contributes to increased efficiency.

- With all of the above in the inventive system of excess air, the aerodynamic resistance of the sections of the main tract included in the excess air circuit, practically does not exceed the aerodynamic resistance in the existing system with the same values of Q _I and t ' _TVP . This is despite a significant increase in the flow of excess air to the heat exchanger and recirculated air through its bypass. The increase in air resistance in the 1st stroke of the air heater is offset by a significant decrease in aerodynamic drag in the 2nd stroke. Thus, according to the calculations [5], the air pressure in the mixer of the main air flow from the excess blower fan will not be higher than in the existing excess air system.

- Additionally, the aerodynamic drag of the main air path is reduced when using the jumper as a bypass for the air heater stroke following the 1st stroke.

- Increases the required amount of temperature taken from the cutoff of excess air in front of the heat exchanger by mixing part of the hot air sent in the "opposite direction" through the jumper (Figure 3).

- The pressure in the cross-section with taps between the air heater strokes is much higher than at the tapping point after its 2nd stroke in the existing system. This, along with a significantly lower temperature of the air in the cross-section directed to the heat exchanger relative to the temperature of the extracted hot air in the existing excess air system, improves the operating conditions of the recirculating air fan in the inventive system, in which the performance of this fan increases.

A comparative analysis shows that the set of features is new. No solutions having similar features have been identified, which allows us to conclude that the proposed technical solution meets the criterion of "significant differences".

The invention is illustrated by drawings made according to the documentation for the proposal for the reconstruction of the existing excess air system in order to take from the cut of the air heater through the air of the P-67 boiler: excess air to the heat exchanger, recirculating excess air bypassing the heat exchanger and discharging excess air.

Figure 1. - The existing excess air system with an air heater of the P-67 boiler of the 800 MW power unit is the basic excess air system.

Figure 2. - Scheme of the air heater to the existing excess air system of the P-67 boiler of the 800 MW power unit.

Figure 3. - A well-known heat extraction system for heat supply using a built-in heat exchanger in the cut of an air heater in the air as applied to a P-67 boiler of an 800 MW power unit.

FIG. 4. - The inventive system of excess air with a jumper and with selection from the cut of the heater: recirculating excess air to the heat exchanger, recirculating excess air, bypassing the heat exchanger, and excess exhaust air in relation to the boiler P-67 power unit 800 MW.

Figure 5. - Scheme of the air heater to the inventive excess air system for the boiler P-67 power unit 800 MW.

Figure 1 presents the existing excess air system in the boiler P-67 of a 800 MW power unit with the calculated parameters of one of its operating modes in 2005 / obtained by the "Tract" program taking into account the operating characteristics of the boiler nodes obtained by the "Reverse" program [6 ].

Feed water with a temperature of t _pv equal to 274 ° C enters the economizer (1), the gas flow from which with a temperature of 393 ° C enters the air heater. At the outlet of the flue gases from the first stroke of the heater through the air (2), their temperature - T _h - is 179 ° C (the adjusted design value of T _h is 162 ° C). After the mixer, air with a temperature of 75 ° C enters the 1st stroke and then through the bypass ducts in the cut of the air heater enters the 2nd stroke (3), from which the hot air exits at a temperature of 315 ° C. From the hot air line, recirculated excess air was taken to the heat exchanger (4), taken to the recirculated excess air line bypassing the heat exchanger (5), and excess exhaust air (6) was taken to the line. The fraction of recirculated air b _RC in the bypass of the heat exchanger is equal to 0.01, the value of Q _IW is 38.8 Gcal / h. After the 2nd stroke, hot air is sent to the furnace (7). The excess air discharge line is closed.

Figure 2 shows a diagram of the air heater of the boiler P-67. Bypass ducts in the cut of the air heater are made according to the Z-cross scheme developed at the Podolsk Engineering Plant.

Figure 3 shows another known system of heat extraction from flue gases with a built-in heat exchanger in the dissection of the air heater in the air and in relation to the boiler P-67 power unit 800 MW in the conditional absence of a recirculation circuit for excess air with a heat exchanger. The fraction of recirculated air (5) - b _rts is equal to the value of b _rts in the basic system of excess air (Fig. 1) 0.01. It should be noted that both known systems: a recirculating excess air system with a heat exchanger and a system with a built-in heat exchanger for dissecting an air heater through the air, have design parameters that are close to each other, including a high value of T _yx .

Figure 4 shows the inventive system of excess air with selection from the cut of the heater through the air recirculating excess air to the heat exchanger, recirculating excess air bypassing the heat exchanger and exhaust excess air. Designations are the same as in figure 1. A jumper with a gate between the lines of excess air to the heat exchanger from the cut-off after the 1st stroke and hot air after the 2nd stroke (8) is shown. In relation to the P-67 boiler, the corresponding calculated parameters are also given. Under the same set values Q _vvto, t and t _{nB TID} for the same calculated value C _'TID equal to 393 ° C, the temperature of the flue gas in the inventive system, reduced excess air at 10 ° C. In this case, the fraction of recirculated air b _RC is equal to 0.15, and the air temperature in the cut of the air heater is 183 ° C against b _RC and the air temperature in the cut in the base system of 0.01 and 201 ° C, respectively. With a fraction of the flow rate of part of the hot air through the jumper b _AC equal to 0.045, the temperature of the recirculated excess air in front of the heat exchanger is 192 ° C. The proportion of air flow through the heat exchanger - b _I - 0.795 against b _I , equal to 0.435 in the base system ( _figure 1). Reset Io accepted closed.

In FIG. 5 shows a diagram of an air heater for the excess air system claimed as an invention with air sampling from a cut of an air heater and with a jumper at bypass ducts in a cut made according to the Z-cross pattern.

A part of the hot air can be directed through the jumper to the day sampling line of a certain increase in air temperature in front of the heat exchanger in order to correct the throughput of the excess air recirculation loop, as well as during the commissioning and development of the new inventive excess air system. It can be used to increase the air temperature in front of the heat exchanger with its nominal heat removal at a reduced load (60%). In this case, the proportion of hot air supplied to the extraction line from the cut through the jumper “in the opposite direction” can be controlled by a gate on the selection line from the split of the air heater (Fig. 4) by covering it.

In order to improve efficiency by reducing the aerodynamic drag of the primary air path at the same, reduced by 10 ° C, the value T _yx and correspondingly increased boiler efficiency by 0.6% from the selection part of the air line from the air preheater crosscuts may be directed through the conduit provided with a slide gate , “In the forward direction” to the hot air line connected to the outlet of the 2nd heater stroke. The "useful" t decrease _tv and _Ta. At the same time, the value of _IWB increases by ~ 8% due to a decrease in the temperature of excess air in front of the heat exchanger to the temperature in the cut.

Thus, the claimed excess air system using jumpers in both directions in the respective conditions has a significant advantage, determined mainly by the lower value of T _ear as before base excess air system (1) and prior known system with integrated heat exchanger in crosscuts air heater through the air (figure 3).

Information sources

1. Sotnikov I.A., Okerblom Yu.I., Itman D.L., Kharkin Yu.A., Marshak Yu.L. The main design and construction solutions for a steam boiler at Kansk-Achinsk brown corners for 800 MW power units. - Thermal Engineering, 1987, No. 8, p.3.

2. A.S. No. 1224417, IPC F 01 K7 / 40. Publ. 04/15/86.

3. Lipets A.U. New ZiO developments on the use of Kansk-Achinsk coal in powerful power units. - Problems of using Kansk-Achinsk coal at power plants. Collection of reports of the All-Russian scientific and practical conference. Krasnoyarsk. 2000.S. 228, Fig. 7.

4. Lipets A.U., Ph.D., Kuznetsova S.M., Rubenkova R.B. "Towards the selection of a thermal circuit for the technical re-equipment of an 800 MW power unit operating on Kansk-Achinsk coal." - Operation and modernization of 800 MW power units. Collection of reports at the international scientific-practical conference November 20-22, 2002 Sharypovo. 2002.S. 148, Fig. one.

5. Aerodynamic calculation of boiler units. Normative method. - Leningrad. Energy, 1977.S. 15.

6. Demo EP, Shifrin V.Ya., Peters V.F., Sokach G.P., Alexandrov A.D. "Reverse program and monitoring of indicators of the state of heating surfaces of boiler units. - Operation and modernization of 800 MW power units. Collection of reports at the international scientific and practical conference on November 20-22, 2002, Sharypovo. 2002. P. 213.

Claims (1)

An excess air system with a multi-way tubular air heater equipped with an air recirculation line with at least one air-water heat exchanger, characterized in that the air is drawn into the recirculation line from the cut-out between the air heater strokes, while the recirculation line is connected by a jumper equipped with a gate with exit from the last stroke of the air heater and with a reset.

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