RU120750U1 - WATER BOILER - Google Patents

Abstract

This utility model relates to waste heat boilers designed to neutralize and utilize the heat of flue gases that depart from gas generating units, for example, from coke oven batteries, dry coke quenching plants, and the like. The essence of the utility model is that the reactor of the recovery boiler additionally contains a flue gas flow distributor, which is located in the said active combustion zone opposite to the zone of contact of the said boron with the reactor, as a result of which two mutually intersecting eddy flows are formed in the reactor, and the recovery boiler also contains an annular collector that adjoins the flue gas supply hog and contains additional flue gas supply pipes to the reactor that are adjacent to the side surface of the flue gas torus, so that the flue gases coming from the annular manifold into the combustion zone of the reactor while moving both of said eddy currents. The technical result of the claimed utility model is to develop a compact waste heat boiler, which is characterized by ease of manufacture and effective neutralization of flue gases.

1 n.p.ph., 4 s.p.f., 5 ill.

Description

FIELD OF TECHNOLOGY

This utility model relates to waste heat boilers that are designed to neutralize and utilize the heat of flue gases that depart from gas generating units, for example, coke oven batteries, dry coke quenching plants, and the like.

The inventive waste heat boiler can be used in coke, metallurgical, chemical and other industries.

BACKGROUND OF THE INVENTION

A recovery boiler is known, international application No.PCT / UA2007 / 000012, which contains a flue gas supply pipe, a flue gas pipe outlet, a reactor containing cyclone combustion chambers, each of which includes a burner device, and into which flue gas pipes are connected tangentially, heat recovery system, including heat exchange surfaces and connected to the reactor and the flue gas outlet pipe. Also, the reactor of the recovery boiler is equipped with an afterburner associated with cyclone combustion chambers and forming the working volume of the reactor with them.

The disadvantages of the known recovery boiler are:

- a large reactor volume and large overall dimensions of the recovery boiler, which is due to the location of cyclone chambers and afterburners in the reactor;

- the large weight of the recovery boiler and the complexity of its manufacture, which is associated with the use of cyclone chambers and an afterburner in the reactor.

The compactness of waste-heat boilers is an important condition for their use in the enterprise, since, usually, waste-heat boilers are additionally used in an already existing streamlined process in order to ensure the neutralization of flue gases, to protect the environment and increase the efficiency of energy use, for example, for using the heat of flue gases leaving the gas generating units, for example, coke oven batteries, dry coke quenching plants, etc. Therefore, the location of waste-heat boilers in the enterprise leads to great difficulties. A particularly acute problem is the location of large-sized waste-heat boilers behind large gas generating units, for example, a coke oven battery, from which, depending on its design, approximately 50,000-120,000 nm / h of flue gases departs, therefore it is clear that for the disposal of large volumes of flue gases Oversized waste heat boilers are required accordingly.

ESSENCE OF A USEFUL MODEL

The objective of this utility model is to develop a waste heat boiler, which is characterized by its compact size, ease of manufacture and effective flue gas neutralization.

Another objective of this utility model is to increase the efficiency of heat recovery of flue gases.

Another objective of the utility model is to expand the arsenal of technical means and capabilities of waste heat boilers.

Other objectives and advantages of this utility model will be identified below as the present description and drawings.

The problem is solved in that the waste heat boiler, characterized by the presence of:

- a reactor, to the lower part of which two burners are adjacent, and a flue gas supply hog adjacent to the side surface of the reactor, while the flue gases that leave the flue gas hog enter the active combustion zone of the reactor, which is located in its lower part,

- flue gas heat recovery systems that enter the reactor of the recovery boiler,

- a flue gas outlet pipe from the reactor, which contains an additional flue gas heat recovery system and at least one smoke exhauster,

according to the claimed utility model, the recovery boiler further comprises:

- a distributor of the flue gas stream that enters from the hog into the reactor of the recovery boiler, wherein the said distributor is located in said active combustion zone opposite to the adjoining zone of the said hog to the reactor, as a result of which two mutually intersecting eddy flows are formed in the reactor,

- an annular collector that is adjacent to the flue gas supply hog and contains additional nozzles for supplying flue gases to the reactor, which are adjacent to the side surface of the reactor so that the flue gases flow from the annular collector into the active combustion zone of the reactor along both of these vortex flows.

In a particular embodiment, the waste heat boiler contains at least one nozzle for supplying fuel to the flue gases that leave the hog in the reactor of the waste heat boiler, wherein said fuel nozzle is located after the adjoining zone of the annular manifold to the bur in the direction of the flue gas in the hog.

In a particular embodiment of the recovery boiler, the flow distributor is made of heating surfaces of the flue gas heat recovery system in the reactor of the recovery boiler.

In a particular embodiment, the recovery boiler contains at least one pipe for supplying air to the flue gases, which are discharged into the reactor of the boiler for recovery, while said pipe for supplying air is located in front of the adjoining zone of the annular collector to the bog along the flue gas flow in the bir .

In a particular embodiment, a flue gas flow regulator is located in the hog, which is located in the zone where the hog adjoins the waste heat boiler reactor.

The use of the said recovery boiler with an annular collector will reduce the reactor volume of the recovery boiler due to the absence of cyclone chambers in the reactor in comparison with the known technical solution.

Also, the use of the inventive waste-heat boiler with an annular collector, which contains additional flue gas supply pipes for supplying flue gases to the reactor in the direction of the two mentioned vortex flows, leads to an effective process of neutralization of flue gases in the reactor of the waste heat boiler.

Also, the use of an annular collector, which is adjacent to the flue gas boron and contains additional nozzles for supplying flue gases to the reactor, which are adjacent to the side surface of the reactor so that the flue gases enter the active combustion zone of the reactor in the direction of each of the mentioned vortex flows, allows to form vortex flows in the reactor of the recovery boiler, and also allows you to eliminate stagnant zones in the reactor and organize the efficient use of fuel supplied to the smoke s that extend from hog reactor HRSG.

The implementation of the distributor of the flow from the heating surfaces of the flue gas heat recovery system in the reactor of the recovery boiler will increase the reliability of the reactor of the recovery boiler, since when the distribution of the stream of refractory materials leads to their rapid destruction, due to constantly changing temperatures.

The use of a nozzle for supplying fuel to the flue gases that leave the boron in the reactor of the recovery boiler, while the said nozzle for supplying fuel is located after the adjoining zone of the annular collector to the bur in the direction of movement of the flue gases in the hog, will allow the fuel to be supplied to the flue gases from the hog to the reactor, to the intersection zone of the vortex flows, which provides adaptive optimization of fuel consumption for neutralization of flue gases by the recovery boiler.

BLUEPRINTS

When considering embodiments of the present utility model, narrow terminology is used. However, the present utility model is not limited to accepted terms and it should be borne in mind that each such term covers all equivalent elements that work in a similar way and are used to solve the same problems.

The drawings of figures 1-5 are graphical explanations of the industrial applicability of the inventive waste heat boiler in an arbitrary scale.

Figure 1 - shows the reactor of the inventive waste heat boiler.

Figure 2 - shows the reactor of the inventive recovery boiler, shown in figure 1, which shows the movement of flue gas flows in the reactor of the recovery boiler.

Figure 3 - schematically shows a waste heat boiler.

Figure 4 - shows an embodiment of the reactor of the recovery boiler, which contains additional nozzles for supplying air to the flue gases.

Figure 5 - shows an embodiment of the reactor of the recovery boiler, shown in figure 4, with the presence of a flue gas flow regulator in the hog, which is located in the zone of contact of the hog with the reactor of the recovery boiler.

IMPLEMENTATION OF A USEFUL MODEL

The inventive waste heat boiler contains a reactor 1 (see FIGS. 1-5), two burners 2 ₁ and 2 ₂ are adjacent to the lower part, and a flue gas supply 3 adjacent to the side surface of the reactor 1, while the flue gases that exhaust from the hog 3, enter the active combustion zone 4 of the reactor 1, which is located in its lower part.

The recovery boiler also contains a flow distributor 5, which is located in the reactor 1 on its side surface in the aforementioned active combustion zone 4 opposite to the adjoining zone of the mentioned flue gas supply boron 3, and due to the flow distributor 5, two eddy flows 6 ₁ are formed in the reactor ₁ and 6 ₂ that intersect with each other in the reactor 1 of the recovery boiler (see figure 4).

Also, the recovery boiler includes a heat recovery system 7, which is located in the aforementioned reactor 1.

The recovery boiler also contains an annular collector 8, which is adjacent to the flue gas hog 3 into the reactor 1 of the recovery boiler in the zone of intersection of two vortex flows 6 ₁ and 6 ₂ . Moreover, the annular manifold 8 contains additional nozzles 9 ₁ , 9 ₂ , 9 ₃ , 9 ₄ and 9 ₅ supplying flue gases from the annular collector 8 to the active combustion zone 4 of the reactor 1. Additional nozzles 9 ₁ 9 ₂ , 9 ₃ , 9 ₄ and 9 ₅ are adjacent to the side surface of the reactor 1 so that the flue gases enter the active combustion zone 4 of the reactor 1 in the direction of the vortex flows 6 ₁ and 6 ₂ (figure 2).

Also, the recovery boiler includes a flue gas outlet 10 (FIG. 3). The pipe exhaust gas 10 from the reactor 1 contains an additional heat recovery system 11 (figure 3) and a smoke exhauster 12.

The recovery boiler also contains nozzles for supplying fuel 13 ₁ and 13 ₂ to the flue gases that leave the hog 3 in the reactor 1 of the recovery boiler, while the nozzles for supplying fuel 13 ₁ and 13 ₂ are located after the adjoining zone of the annular manifold 8 to the hog 3 flue gas movement in the hog 3.

The inventive recovery boiler operates as follows: flue gases that are removed from the generating unit, for example, from a coke oven battery (not shown in the figures), enter the burs 3, through which they go to the reactor 1 of the recovery boiler (examples of boiler connection schemes - utilizer for coke oven batteries are disclosed in patents No. RU2373255, UA41178, UA40854 and UA40853).

The flue gases that leave the hog 3 into the recovery boiler are divided into two flue gas streams.

The first flue gas stream leaves the hog 3 in the reactor 1, while the first flue gas stream is additionally supplied with fuel using the fuel supply pipes 13 ₁ and 13 ₂ .

The second stream of flue gases leaves the hog 3 in the annular collector 8.

In this case, the first flue gas stream is diverted to the active combustion zone 4 and the intersection zone of two vortex flows 6 ₁ and 6 ₂ in the reactor 1, while the active combustion zone 4 is formed using two torches of the burners 2 ₁ and 2 ₂ to which fuel is supplied ( the circuit for supplying fuel and air to burners 2 ₁ and 2 _{2 is} not shown in the figures).

In the active combustion zone 4, two mutually intersecting vortex flows 6 ₁ and 6 _{2 are formed} , which have a length along the entire height of the reactor 1. Moreover, due to the heat recovery system 7, which is made in the form of heating surfaces placed on the inner surface of the reactor 1, heat is removed from flue gases that are in the reactor 1.

As mentioned above, the second part of the flue gas stream flows into the annular collector 8 (figure 2). From the annular collector 8, flue gases are discharged through additional nozzles 9 ₁ , 9 ₂ , 9 ₃ , 9 ₄ , and 9 ₅ into the active combustion zone 4. In this case, the flue gases from the additional nozzles 9 ₁ and 9 ₂ are discharged tangentially along the movement of the vortex stream 6 ₁ , and the flue gases from the additional nozzles 9 ₄ and 9 ₅ are discharged into the reactor 1 tangentially in the direction of the vortex stream 6 ₂ . As for the pipe 9 ₃ , flue gases are removed from it in the direction of the vortex flows 6 ₁ and 6 ₂ due to the supply of flue gases through additional pipes 9 ₁ , 9 ₂ , 9 ₃ , 9 ₄ and 9 _{5 the} vortex flows are amplified and stabilized 6 ₁ and 6 ₂ in the working volume of the reactor 1.

It should also be noted that in the reactor 1, the vortex flows 6 ₁ and 6 ₂ collide, which leads to active mixing and an increase in the degree of neutralization of flue gases, and also leads to a decrease in the working volume of the reactor 1.

From the reactor 1, the flue gases are discharged into the flue gas outlet pipe 10, in which an additional heat recovery system 11 is located. In this case, the flue gases in the recovery boiler are driven by the exhaust fan 12. From the flue gas outlet 10, the flue gases go into the chimney ( figures not shown).

Figure 4 shows an embodiment of a waste heat boiler, which further comprises nozzles for supplying air 14 ₁ and 14 ₂ to the flue gases that leave the hog 3 in the reactor 1 of the waste heat boiler. In this case, the air supply pipes 14 ₁ and 14 ₂ are located in front of the adjoining zone of the annular collector 8 to the hog 3 along the flue gas in the hog 3. Thanks to the air supply pipes 14 ₁ and 14 ₂ it is possible to uniformly maintain the set value of the coefficient of excess air in the flue gases, which leads to an effective neutralization of flue gases in the waste heat boiler, which is also an advantage of the claimed utility model.

It is clear that the above presents one of the possible embodiments of the present utility model. The present utility model is not limited to the embodiment that has been set forth above and shown in the figures.

For example, a variant is possible when a flue gas flow regulator 15 is located in the hog into the reactor 1 of the inventive waste heat boiler (Fig. 5). Thanks to the use of the said flow regulator 15, it is possible to control the rate of supply of flue gases from the hog 3 to the reactor 1, which is relevant when changing the operating mode of gas generating units.

TECHNICAL RESULT

The technical result of the claimed utility model is to develop a compact waste heat boiler, which is characterized by ease of manufacture and effective neutralization of flue gases.

Also the technical result of this utility model is to increase the efficiency of heat recovery of flue gases.

Claims (5)

1. A waste heat boiler characterized by - a reactor, to the lower part of which two burners are adjacent, and a flue gas supply hog adjacent to the side surface of the reactor, while the flue gases that leave the flue gas hog enter the active combustion zone of the reactor, which is located in its lower part, - flue gas heat recovery systems that enter the reactor of the recovery boiler, - a flue gas outlet pipe from the reactor, which contains an additional flue gas heat recovery system and at least one smoke exhauster, characterized in that the waste heat boiler further comprises - a distributor of the flue gas stream that enters from the hog into the reactor of the recovery boiler, wherein said distributor is located in said active combustion zone opposite to the adjoining zone of the said hog to the reactor, as a result of which two mutually intersecting eddy flows are formed in the reactor, - an annular collector that is adjacent to the flue gas supply hog and contains additional nozzles for supplying flue gases to the reactor, which are adjacent to the side surface of the reactor so that the flue gases flow from the annular collector into the active combustion zone of the reactor along both of these vortex flows. 2. The waste heat boiler according to claim 1, characterized in that it comprises at least one nozzle for supplying fuel to the flue gases, which leave the boron in the reactor of the waste heat boiler, said fuel nozzle being located after the adjoining zone of the annular collector to the hog along the flue gas in the hog. 3. The recovery boiler according to claim 1 or 2, characterized in that the flow distributor is made of heating surfaces of the flue gas heat recovery system in the reactor of the recovery boiler. 4. The recovery boiler according to claim 1 or 2, characterized in that it contains at least one pipe for supplying air to the flue gases, which are discharged into the reactor of the boiler for recovery, while said pipe for supplying air is located in front of the adjoining zone of the annular collector to the hog along the flue gas in the hog. 5. The recovery boiler according to claim 1 or 2, characterized in that the flue gas flow regulator is located in the hog, which is located in the zone where the hog adjoins the reactor of the recovery boiler.