RU2484402C1 - Device for heat utilisation of condensation of water vapour and cleaning of waste gases of power plant - Google Patents

Abstract

FIELD: power industry.

SUBSTANCE: gas flow enters a preliminary gas cleaning step made in the form a dry cyclone, and then, to the heat utilisation unit with the main cleaning step, which is made in the form of a centrifugal bubbling unit with liquid absorbent. At that, centrifugal bubbling unit is placed into a sealed casing made in the form of a hollow cylindrical heat exchanger, and inner space between itself and external housing of the heat utilisation unit and external housing of dry cyclone is filled with vacuum powder insulation.

EFFECT: device increases efficiency of utilisation and cleaning of waste gases.

2 cl, 3 dwg

Description

The invention relates to the field of power engineering, and more precisely to the utilization of heat of condensation of water vapor and purification of flue gases of a power plant, and can find application in chemical, metallurgical, fuel and energy and other industries related to the disposal and destruction of substances harmful to human life .

It is known that a further increase in the efficiency and efficiency of energy complexes, including thermal power plants, is associated with the use of condensation heat of water vapor from flue gases and their deep cleaning of substances harmful to humans (Burdukov A.P., Dubinsky Yu.I., Zubkov V.A. Utilization of heat of condensation of water vapor of exhaust gases of solid energy fuels. Heat Power Engineering. No. 2. 1996, p.14-16).

The closest invention in terms of features to the claimed device for heat recovery of condensation of water vapor and purification of the flue gases of a power plant is a system for heat recovery and purification of exhaust gases (RF Patent No. 2175101 “System for the utilization of heat and purification of exhaust gases”. Cl. F28C 3/16 2001).

The system includes a heat exchanger in the form of a vertical housing with inlet and outlet nozzles, divided by a horizontal partition into chambers of heating and heated media, in which vertical heat pipes are installed, placed with their condensers in the chamber of the heated medium, and evaporators in the chamber of the heating medium; means for cleaning gases, made in the form of a wet Venturi scrubber connected to its inlet with a supply duct of the power plant, and the output to the inlet of the heat exchanger; additional wet Venturi scrubber, which is connected to the blowing air supply pipe and the heating chamber of the heat exchanger.

The disadvantages of this invention, taken as a prototype, is that this system does not allow for complete utilization of the heat of the exhaust gases, but only part of it left after the gases passed its first wet cleaning - the main venturi scrubber. In addition, the wet coagulation of dust particles in this primary stage will not purify the flue gases, but, on the contrary, will complicate their further purification and utilization of heat.

The second stage of cleaning this system has the following drawback: the liquid sludge that has entered the internal space of the utilizer during its zigzag motion will cover the surface of the heat pipe evaporators with an insoluble tar deposit, which reduces the efficiency of the heat exchanger.

The task of the invention is to eliminate the above disadvantages inherent in the known system by creating and implementing a fundamentally new design of a device for utilizing the heat of condensation of water vapor and cleaning the flue gases of a power plant.

This problem is solved due to the new design of the device for utilizing heat of condensation of water vapor and purifying the exhaust gases of a power plant with a more efficient system for utilizing heat and purifying the exhaust gases with minimal costs for its implementation, including operating costs.

A device for recovering heat of condensation of water vapor and cleaning the exhaust gases of a power plant, including a preliminary cleaning stage, a heat exchanger body with inlet and outlet pipes and a heat recovery unit with a main cleaning stage.

The specified technical result is achieved by the fact that the preliminary cleaning stage in the proposed device is made in the form of a dry cyclone with a tangential gap supply of the gas to be cleaned; the heat recovery unit with the main cleaning stage is made in the form of a centrifugal bubbler apparatus with a liquid absorbent, which is hydraulically connected via gas to the outlet pipe of a dry cyclone with a tangential slot supply of the gas to be cleaned and the outlet pipe of the heat recovery body; a centrifugal bubbler apparatus with a liquid absorbent is vertically mounted above a dry cyclone and enclosed in an additional protective tight enclosure made in the form of a hollow cylindrical heat exchanger. The indicated technical result is also achieved by the fact that the space located between the heat recovery body and the outer shell of the dry cyclone with the protective casing of the centrifugal bubbler apparatus is made in the form of a sealed volume and filled with vacuum-powder insulation.

Figure 1 shows a General view (in section) of a device for utilizing heat of condensation of water vapor and purification of flue gases of a power plant.

Figure 2 shows a cross section of the device along aa in figure 1. In Fig.3 shows a cross section of the device along BB in Fig.1. Information confirming the possibility of implementing the claimed invention using the specified technical result, are as follows.

The claimed invention for the recovery of heat of condensation of water vapor and purification of the exhaust gases of a power plant includes an outer casing 1 with an inlet pipe 2 and an outlet pipe 3, a dry cyclone body 4 with a hopper 5 for collecting particulate matter and a pipe 6 for removing them, tangential input 7 dry cyclone gas, slotted grate 8 for uniform gas distribution, dry cyclone outlet pipe 9, centrifugal bubbler apparatus 10, manifold 11 with inlet pipe 12 for introducing liquid absorbent into centrifugal bubbler the apparatus, the spent absorber chamber 13 with a nozzle 14 for its output, a hollow cylindrical heat exchanger 15 with a nozzle 16 for water input and a nozzle 17 for its output, and adjusting cones 18, 19 of a dry cyclone. In this case, the space 20 formed by the housing 1 of the utilizer and the housing 4 of the dry cyclone with a cylindrical heat exchanger 15 of the centrifugal bubbler apparatus 10 is made in the form of a vacuum volume and is filled with vacuum-powder insulation (not shown in the drawing).

This device is included in the thermal circuit of the power plant and is connected directly in front of the exhaust fan to the exhaust gas outlet device of the power plant. This device is designed to recover heat that is released into the atmosphere with flue gases in the form of latent heat of vaporization of water vapor generated both by evaporation of moisture from the working mass of fuel and pyrogenetically as a result of combustion of its combustible mass. In practice, in order to reduce the relative humidity of the gases leaving the gas treatment device in a state of full saturation with water vapor, they mix hot air or part of the hot feed gas, which is not always justified from an economic point of view. When deep, below the temperature of the beginning of condensation of water vapor, cooling of the flue gases with the help of this device, condensation of water vapor occurs, both due to the departure of moisture, and as a result of lowering the temperature of the remaining gases. At the same time, the dual cleaning system of this device, including the “dry” and “wet” stages, guarantees complete cleaning of the exhaust gases from both large solid particles of unburned fuel and suspended small particles (aerosols). The hot exhaust gases leaving the power plant at a temperature of 100-160 ° C through the inlet pipe 2 go directly to the tangential inlet 7 of the dry cyclone. Using the slotted grating 8, the gas is evenly distributed around the circumference and twisted. Under the action of the centrifugal component of the vortex flow velocity, solid particles are pressed against the inner wall of the dry cyclone body 4. When interacting with the wall, their speed decreases, and under the influence of gravitational force they move to the base of the dry cyclone and fall into the hopper 5, from where they are periodically removed from the dry cyclone through the nozzle 6. At this time, the main vortex stream of the gas being purified, freed from solid particles, changes its direction to the opposite and enters the outlet pipe 9 of the dry cyclone. Then, the gas to be cleaned is sent to a centrifugal bubbler apparatus 10. Here, when meeting with a liquid absorbent, the exhaust gases not only are finally cleaned of all foreign particles and aerosols, but also give up their heat, and due to the heat of the phase transition, additional heat is released and the cleaned gas. The centrifugal bubbler apparatus in this case is used both as a wet scrubber and as a contact heat exchanger (gas-liquid). The liquid absorbent under the action of a centrifugal field is squeezed to the periphery, and the incoming cleaned gas breaks up the absorbent into micron particles. As a result, the surface of the liquid absorbent increases tens of times, and its chemical activity increases. It should be noted that this crushing of liquid absorbent is more effective than spraying it in wet Venturi scrubbers. Therefore, a centrifugal bubbler device captures the micro suspension, while in wet Venturi scrubbers the micro suspension is not captured, but slips past the absorbent. At the same time, the liquid absorbent in the centrifugal bubbler apparatus itself breaks the gas to be cleaned into small bubbles, which are distributed inside the vortex ring layer in accordance with their weight and volume and move inside this ring along well-defined paths. In this case, water vapor located in the gas to be cleaned is absorbed by the liquid absorbent and cooled on the inner surfaces of the centrifugal bubbler apparatus and ultimately accumulates in the chamber 13 for collecting the spent absorbent. Next, the spent liquid absorbent through the pipe 14 is removed from the centrifugal bubbler apparatus 10 for regeneration (a regenerator is not shown conventionally), and then through the inlet pipe 12 and the collector 11 is again introduced into it. In this case, all the heat received by the centrifugal bubbler apparatus 10 and the dry cyclone from the gas to be cleaned is absorbed by the water of the heat exchanger 15, which is then sent through the pipe 17 to the consumer, for example, to a heat pump or returned to the cycle of the power plant. For more efficient operation of the heat exchanger 15, it is surrounded, together with a dry cyclone, with a sealed volume, in which vacuum can be maintained both due to vacuum-powder insulation and by connecting this space to a vacuum pump (not shown in the drawing).

The technical effect of the use of the invention is as follows.

The proposed device for the recovery of heat of condensation of water vapor and purification of the exhaust gases of a power plant has a low metal consumption, is simple to manufacture and reliable in operation. The degree of purification of the flue gases from the power plant using this device is so high that it excludes the use of other additional devices before the gases are released into the atmosphere. From an economic point of view, it is efficient and reliable during operation. Savings from the use of this device, especially when using low-calorie brown coals and water-coal suspensions as a fuel, can arise both due to the utilization of additional heat, and due to a decrease in the volume of gases emitted into the atmosphere.

Thus, the above information shows that when using the claimed invention, the following combination of conditions:

- a tool embodying the claimed invention in its implementation, is intended for use in industry, namely in the field of power engineering, in particular as equipment for the utilization of heat of condensation of water vapor and purification of flue gases of a power plant;

- for the claimed invention in the form described in the independent clause of the claims, the possibility of implementation using the methods and methods described above or known prior to the priority date is confirmed;

- means embodying the claimed invention in its implementation, is able to ensure the achievement of the perceived by the applicant technical result.

The advantage of the claimed invention is that as a result of its implementation, the degree of purification of the flue gases and the efficiency of utilization of their heat are increased, and the simplicity of the manufacture of its design significantly reduces all types of costs for cleaning and utilizing the heat of the flue gases, including operational, while ensuring a high degree of reliability .

Claims (2)

1. A device for recovering heat of condensation of water vapor and cleaning the exhaust gases of a power plant, including a preliminary cleaning stage, a heat exchanger body with inlet and outlet pipes and a heat recovery unit with a main cleaning stage, characterized in that the preliminary cleaning stage in it is made in the form of a dry a cyclone with a tangential slot supply of the gas to be purified, and the heat recovery unit with the main cleaning stage is made in the form of a centrifugal bubbler apparatus with a liquid absorbent, which it is automatically connected by gas to the outlet pipe of the dry cyclone with a tangential slot supply of the gas to be cleaned and the outlet pipe of the heat recovery body, while the centrifugal-bubbler apparatus with a liquid absorbent is vertically mounted above the dry cyclone and enclosed in an additional, sealed protective casing made in the form of a hollow cylindrical heat exchanger. 2. The device according to claim 1, characterized in that the space located between the body of the heat recovery unit and the outer casing of the dry cyclone with the protective casing of the centrifugal bubbler apparatus is made in the form of a vacuum volume and is filled with vacuum-powder insulation.

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