RU2135889C1 - Boiler unit - Google Patents

Abstract

FIELD: steam generating plants. SUBSTANCE: boiler unit has vertical shell filled to the top with liquid heat carrier whose wall is made from capillary-porous hydrophilic material with radial orientation of through pores; source of thermal energy is located inside shell. Effective diameter of pores is calculated by formulae on the condition of position of interphase across the whole with of capillary-porous wall by pressure of steam in boiler. Outer surface of wall is coated with lyophobic permeable coat. EFFECT: intensification of steam generation due to hydrophilic material of wall; possibility of selecting of required rating of boiler unit due to determination of effective diameter by formulae. 2 cl, 1 dwg

Description

 The invention relates to boiler plants for steam generation.

 Steam boiler units functionally consist of two main parts of the furnaces, in which heat energy is generated from fuel, and heat exchangers, in which heat energy is transferred to the liquid heat carrier, which is heated and transferred to the vapor state with the required pressure and temperature, according to the conditions of the boiler application.

 The process of burning fuel in the furnaces of boiler units does not provide a uniform distribution of heat fluxes to the surface of the heat exchangers, therefore, in steam generating plants there are three groups of heat exchangers: steam generators, superheaters and economizers, each of which takes into account the heat transfer conditions in individual zones of the furnace and boiler unit and agrees with these conditions the ability of the coolant to effectively remove heat.

Thus, the existing boiler-generating steam generating units have the following disadvantages:
- the values of the specific heat influx to the surface of the heat exchangers make it necessary to take measures to exclude crisis phenomena during boiling of a liquid coolant;
- boiler furnaces and heat exchangers have large dimensions and metal consumption, which requires relatively large volumes and terms of repair and maintenance work.

 The aim of the invention is to remedy these disadvantages.

 The closest set goal corresponds to a boiler unit, which is a cylindrical body located vertically, filled to the top with liquid heat carrier, with one central cylindrical channel, the wall of which is made of capillary-porous material (AS USSR N 644997), and a heat source is located inside the channel . This boiler unit is selected for the prototype of the invention.

 However, in the said boiler unit, heat transfer from the heat energy source to the porous material is carried out due to conductive heat transfer from the wall of the heat energy source to the wall of the porous material due to the tight pressing of the wall of the heat energy source to the porous wall. At the same time, the evolved liquid vapor is discharged into longitudinal channels of rectangular cross section located along the perimeter of the surface of the heat energy source along its axis.

Meanwhile, radiation heating is one of the most effective methods of heat transfer, since the carrier of energy is electromagnetic waves emitted by the surface of a solid body, heated, for example, by a gas flame, in the direction of a heated object in the absence of any intermediate heat transfer medium. The magnitude of the radiation flux is proportional to the fourth degree of the temperature of the radiating surface, which makes it possible to reduce the size of the active heat-transfer surface by increasing its temperature and radiation spectrum while maintaining the total power of the generated energy. Infrared emitters emit energy in the wavelength range from 1 to 7 microns, well absorbed by solids. Methods of gas burning in flame and flameless infrared emitters with a closed reaction part - radiation tubes have been developed and continue to improve (see Kreinin EB, Kafirin Yu.P. "Gas Burning in Radiation Tubes." Nedra, L., 1986 p. 183). Domestic radiation pipes produced for metallurgical needs have a fuel energy efficiency of up to 88% at a temperature of flue gases +200 ^o C with a thermal power of 5 to 104 kW and a radiation flux density of 0.6 to 6.0 W / cm ² . The unevenness of heat transfer along the surface of the radiation pipe is estimated by the temperature difference and at a maximum surface temperature of the pipe 940 - 1050 ^o C is 1.5 - 2%. Methods of gas combustion in radiation pipes ensure the content of harmful impurities in the combustion products within the limits of MPC.

 The use of radiation gas pipes as heat sources in boiler units solves the problem of reducing dimensions, metal consumption, maintainability, environmental cleanliness and uniformity of heat flow to the surface of heat exchangers. Radiation pipes can change the design of boiler units according to the type of use of fuel assemblies in nuclear reactors.

 In the prototype, the process of evaporation of the liquid is organized as it takes place in heat pipes ("Heat pipes: theory and practice". Part 1, 2. Minsk, 1990).

 The process of liquid evaporation in porous evaporators of heat pipes is carried out with the supply of thermal energy from the heating surface located under the saturated liquid in the porous layer. With intensive heat supply, vaporization begins on the heating surface under a porous layer saturated with liquid. Vapors of liquid break through the channel in this layer to reach the phase boundary with the ablation of a part of the liquid, which was observed during the studies.

The capillary-porous material must be hydrophilic, which ensures capillary absorption of liquids and the pressure of saturated vapors above the evaporating meniscus of the liquid in the capillary is less than in the absence of capillary action less
ΔP = σ / D, (1)
where σ is the coefficient of surface tension, D is the diameter of the capillary.

 The above contributes to the intensification of the process of vaporization.

 The pores of the capillary-porous material have a radial orientation for organizing a directed flow of liquid and vapor. The external (cold) surface of the capillary-porous channel wetted by the liquid must be covered with a lyophobic permeable coating, for example, of fluoroplastic, or polyethylene to prevent liquid from penetrating through the channel wall before the boiler unit is switched on.

(2)
где T_ж-T_н - перегрев жидкости;
σ - коэффициент поверхностного натяжения;
r - теплота фазового перехода жидкость - пар;
P_оп - плотность пара при температуре насыщенного пара T_п;
R_кр - критический радиус зародыша парового пузыря.The dependence of the critical radius R _cr of the vapor bubble nucleus in an overheated liquid on the liquid overheating (T _W -T _n ) and on the properties of the liquid (Subbotin V. I., Sorokin D.N., Ovechkin D.M. et al. "Heat transfer at boiling of metals in conditions of natural convection ". M., Science. 1969)

(2)
where T _W -T _n - overheating of the liquid;
σ is the coefficient of surface tension;
r is the heat of the liquid-vapor phase transition;
P _op - vapor density at a temperature of saturated steam T _p ;
R _cr - the critical radius of the vapor bubble embryo.

Heating and overheating of the liquid coolant during its movement in the capillary-porous wall will go on until the degree of overheating comes into line with the effective pore diameter D = 2R _cr and C _p (T _w -T _n ) = r and the liquid from the meniscus goes to par.

где C_р - теплоемкость жидкого теплоносителя, теплофизические свойства теплоносителя в формуле (3) следует брать при давлении пара в котельном агрегате.Formula (1) for the effective pore diameter will take the form

where C _p is the heat capacity of the liquid coolant, the thermophysical properties of the coolant in the formula (3) should be taken at a vapor pressure in the boiler unit.

 Formula (3) allows you to determine the effective pore diameter of the capillary-porous material of the wall of the Central channel of the boiler unit by the value of the vapor pressure in the boiler unit.

 Thus, as an invention, a boiler unit is proposed, the scheme of which is shown in the drawing.

 The boiler unit is a vertically arranged housing 1 filled with liquid to the top, with a central cylindrical channel 2 coaxially located in it with a capillary-porous hydrophilic material wall 3 with a radial orientation of through pores, the diameter of which is determined by formula (3), along the axis of which with an annular gap 4 for the passage of liquid vapor placed radiation source of energy 5, mounted on the end caps 6 of the housing 1.

 The boiler unit has a pipe 7 for supplying fluid and a pipe 8 for outputting steam. The outer surface of the capillary-porous wall 3 of the channel 2 is covered with a lyophobic permeable coating 9, for example, of fluoroplastic or polyethylene.

 The heat energy source 5 by the infrared radiation through the gap 4 heats the surface of the capillary-porous wall 3 of the central channel 2. Through the pipe 7, excess pressure is applied to the liquid in the cavity of the housing 1, which forwards the liquid through the lyophobic permeable coating into the pores of the hydrophilic porous wall 3, where, moving towards the heat flux from a radiation heat source, the liquid heats up and evaporates. Steam enters the annular gap 4, and absorbing part of the spectrum of radiation, overheats and is removed from the boiler unit through the pipe 8.

 By changing the pressure drop between the liquid in the cavity of the housing 1 and the steam in the annular cavity 4, as well as by changing the power of the radiation heat source 5, it is possible to adjust the steam parameters and the steam output per module of the boiler unit.

 As a heat source, an electric heater (TEN), a gas or liquid heat source such as a radiation pipe or a fuel cell of a nuclear reactor in the radiation heat transfer mode can be used.

 At present, the production of a large range of capillary-porous materials has been mastered, technological methods have been developed for the production of such materials with desired properties such as bulk porosity, permeability, effective thermal conductivity, and a range of pore changes with respect to a certain nominal value. Methods have been developed for the experimental determination of these characteristics for a particular material. The above allows when designing the boiler unit under discussion for a given capacity and for given steam parameters to choose the material for the manufacture of the capillary-porous wall of the central channel using a selected radiation heat source.

 The development and implementation of the boiler units of the type under discussion will stimulate the development of radiation heat sources oriented to the use in these units. The main direction of such developments can be an increase in the radiation flux density, as well as an increase in the energy and environmental indicators of the process of converting potential fuel energy into infrared radiation energy.

Unlike existing boiler units, the proposed installation allows you to:
- conduct experimental testing and refinement of a full-scale industrial module of the installation;
- carry out repairs and reconstruction of the existing boiler unit by replacing obsolete and spent their resources with new or improved;
- change the total capacity of the boiler unit by varying the number of modules of the same type, which allows you to have a wide range of boiler units from designed for an individual consumer for household purposes to large-scale TPPs and TPPs.

 The use of capillary-porous walls with through pores in the opposite direction of heat and mass flows as a heat exchanger allows not only heating the liquid to a boiling point within a wall thickness of several millimeters, but also evaporating it without crisis phenomena and the risk of formation of corrosive deposits. In this case, the effective pore diameter is calculated by the formula (3) from the condition of ensuring the location of the phase boundary in the thickness of the capillary-porous wall according to the vapor pressure in the cavity of the boiler unit. The specified meets the criterion of "significant difference".

 The use of radiation heat sources with stable energy and environmental characteristics allows, in combination with a capillary-porous heat exchanger in the form of a wall, to reduce the size of the boiler unit, opening up the possibility of switching to the modular designs of these units as nuclear reactors, distinguished by operational maintainability, availability for continuous improvement, and the possibility of development a wide range of boiler units in terms of power based on a standard module. This meets the criterion of "positive effect".

Claims (2)

1. The boiler unit, which is a cylindrical housing located vertically, filled to the top with liquid heat carrier, with one central cylindrical channel, the wall of which is made of capillary-porous material, and a heat energy source is placed inside the channel, characterized in that the capillary-porous material is selected hydrophilic with the radial orientation of the through pores, the effective diameter of which is determined by the formula

where C _p is the heat capacity of the liquid coolant;
r is the heat of the liquid-vapor phase transition;
σ is the coefficient of surface tension;
ρ _op - vapor density of a saturated liquid;
T _n - vapor temperature of a saturated liquid.  2. The boiler unit according to claim 1, characterized in that the outer surface of the capillary-porous wall of the channel is coated with a lyophobic permeable coating.