BG63581B1 - Water heating boiler - Google Patents

Abstract

The boiler can be used as a basic source of heat in building of heating supply networks for centralized heating. It ensures the effective course of the firing process making use of two types of fuel: heavy oil and natural gas, and reducing the quantity of the injurious emissions discharged into the atmosphere and increasing the operational safety and reliability. The boiler includes a housing (1) in which a furnace chamber (4) and convective packages (7) are fitted, and between housing (1) and the above components there is a heat-exchanging screen (3) made of gas impermeable membrane parts. In the chamber (4) there are torches (5) fitted at two levels. Torches (5) can be directed at an angle towards the horizontal and the vertical axis of the boiler. Above the chamber (4) there are at least three convective packages (7). 3 claims, 7 figures

Description

Technical field

The invention relates to a boiler that can be used as a main heat source for the construction of district heating networks for buildings in large cities.

Current state of the art

Hot water boilers are known for the production of hot water, which consist of a housing hung on a columnar supporting structure, with the active elements of the boiler attached to the housing. Inside the dimensions of the boiler, a furnace chamber and a convective shaft in a tower design are formed sequentially from below.

In the lower part of the furnace chamber there are connecting pipelines between the district heating network and the heating surfaces. On the front and back wall of the furnace chamber, to the housing, are mounted 16 pcs. gas-oil burners, and below them there are individual fans for each burner. In the upper part of the housing convective surfaces are formed, made as two pieces of convective packets of smooth tubes and above the convective packets there is a gas channel for exhaust exhaust to the chimney.

Between the dimensions and the active part of the boiler - the furnace chamber, there are heat exchange screen walls. The described construction of a hot water boiler is most often used as a peak heat source, which implies operation in short periods of time with relatively variable load.

The design of the boiler creates the conditions for operation with a high-speed furnace chamber, which can be observed incomplete combustion of the fuel with the accompanying low efficiency, low operational safety in different modes of operation - starting, stopping, switching to work from one type of fuel to another type of load regime, negative environmental impact.

The boiler's thermal load is the result of the number of burners in operation, with incomplete combustion of the fuel. The unburned part of the fuel is accumulated in the convective packages, which creates conditions for self-ignition and fire occurring when the boiler is stopped. At the same time, the high temperature level in the furnace chamber causes the generation of thermal nitric oxide, which, when working with fuel oil or gas, exceeds the limit values set by environmental requirements.

A well-known boiler is known (Lyulin Heating Plant, Station No. 5), comprising a housing with a heat-exchange membrane containing gas-exchange membrane elements therein, as well as three convective smooth-tube packages located at the top of the housing. Six burners are mounted on the boiler body, arranged on two levels, respectively in horizontal lines.

The well-known boiler described above has the aforementioned disadvantages, manifested mainly in the course of an ineffective combustion process, which in turn also affects the operational reliability of the boiler. At the same time, the boiler is an environmental air pollutant. With continuous operation of the boiler with constant load, the first rows of pipes from the lowest convective package are burnt.

SUMMARY OF THE INVENTION

Given the disadvantages known from the described prototype, it is an object of the invention to provide a boiler for use as a primary heat source. It must be of increased combustion process efficiency and operational reliability to be able to be operated at maximum parameters for extended periods of time, ie. as the main heat source.

The object of the invention is solved by a new construction of a boiler consisting of a housing suspended on a columnar supporting structure inside which a furnace chamber and a convective shaft are formed. Between the housing and the furnace chamber there are heat exchange screens made of gas-tight membrane elements. Burners are mounted on the heat exchangers.

Horizontally oriented convective packages are arranged one above the other in the convective shaft and a gas channel is formed above them.

According to the invention, the convective packages are self-supporting, made of membrane panels and are at least three. The burners are four or six pieces, arranged opposite on two levels, respectively bottom row - at height h = 1/3 Np. and the top row h _rr = 1/2 Np, where Np. is the height of the oven chamber. The burners are inclined downwards at an angle of 5 to 12 °.

According to one embodiment of the boiler, the burners are six and are arranged on two levels in horizontal lines, respectively, three pieces on opposite screens.

According to another variant embodiment of the invention, the burners are six and staggered three on a screen such that a low-lying burner on one level is positioned against a low-level burner on the other level.

According to a third embodiment of the boiler, there are four burners arranged diametrically on opposite screens, whereby the angle β of the inclination of the burners along the horizontal axis of the boiler to the center of the furnace chamber varies from 0 to 12 °.

The boiler according to the invention is distinguished by its high efficiency, which is expressed in operation at prolonged high loads with increased efficiency due to the efficient flow of the combustion process. Due to the proper arrangement of the burners in the furnace chamber, as well as the proper targeting of the gas fuel jets, complete combustion of the fuel is achieved, increasing the power of the boiler to that of the known boilers used as main heat sources by 20%. At the same time, the temperature of the exhaust flue gas is significantly reduced by about 30 ° C and as a result of the above mentioned advantages the efficiency of the boiler operation is increased by 3-5%.

Description of the figures

Exemplary embodiments of the boiler according to the invention are shown in the figures, of which:

Figure 1 is a diagram of one of the possible embodiments of a six-burner boiler arranged on two levels in horizontal lines;

2 is a cross-sectional view of the boiler of FIG. 1;

Figure 3 is an axonometric diagram of a variant embodiment of a four-burner hot water boiler;

Figure 4 is a schematic sectional view of a furnace chamber according to a second embodiment of the boiler with four burners;

Figure 5 is a graphical representation of the trajectory of the combustion particles in a 6-burner oven in horizontal lines;

Figure 6 is a graphical representation of the trajectory of the combustion particles in a furnace with 4 burners;

Figure 7 is a graph showing the temperature variation of the exhaust gases at different boiler loads and different inclination of the burners.

Examples of carrying out the invention

The hot water boiler of the invention consists of a housing 1 hung on a column support frame 2. On the inner surface of the housing 1 there are also heat exchange screens 3 made of gas-tight membrane panels. In the lower part of the housing 1 is a furnace chamber 4 of height H bp, in the area of which four or six burners 5, which are arranged opposite on two levels, are fixed to the screens 3. The lower row of burners is formed at a height of _bd = 1/3 of the height of the furnace chamber H bp, and the upper row of burners - at a height h _rr = 1/2 H bp. All burners are tilted down at an angle of 5 to 12 °. As shown in FIG. 1, a fan 6 is mounted to the side of the housing 1 to supply the air required for the combustion process in the furnace chamber 4.

If necessary to improve the combustion process, a steam vaporizer not shown in the figures may be included in series 6 to the fan 6. Above the furnace chamber 4 are housed at least three convective self-supporting packages 7 made of membrane panels representing thick-walled tubes connected to each other by a rail. Above the convective packages 7, in the upper part of the housing 1, a gas channel 8 is formed for exhaust flue exhaust.

By means of pipelines 9, the boiler connects to the water supply system, and additional pipeline connections 10 between the heating surfaces are provided in the furnace chamber 4, which allow the circulation to be changed.

According to an embodiment of the invention, as shown in Figures 1, 2 and 5, the burners 5 are six in number and are arranged in horizontal lines, respectively, in three pieces on opposite screens.

According to another embodiment of the boiler according to the invention, as shown in FIG. 3, 4 and 6, the burners 5 are four in number, arranged diametrically on opposite screens, i.e. on two levels, two burners per screen, with a burner on the opposite screen adjacent to a downstream burner on one screen. Typical of the described embodiment is that the burners 5 are inclined and along the horizontal axis of the boiler to the center of the furnace chamber 4 at an angle β of 0 to 12 °.

According to a third embodiment, not shown in the drawings, the boiler has six burners mounted checkered on two levels with three burners on opposite screens. In addition, a burner on the top row of the opposite screen is mounted against each burner on the bottom row of one screen.

In all three embodiments of the invention described, the burners 5 are so arranged at the height of the furnace chamber 4 that a good interaction between the opposing developing flares, a uniform velocity profile and a good cross-section are shown, as shown in FIG. 5 and 6, i. efficient combustion process is achieved.

Use of the invention

The boiler is used as the main heat source in large heating plants for heating water and supplying it to buildings with central heating.

The boiler is operated by combustion of the combustion chamber in the furnace 4 through the supply of air through the fan 6. Effective combustion is ensured by directing the gas jets of the burners 5 into the furnace chamber. The combustion products transfer their heat to the heated fluid through the screen 3 and the convective packets 7, whose membrane implementation significantly improves the heat transfer efficiency as well as the operational reliability. Exhaust fumes leave the boiler through the gas channel 8.

Claims (4)

1. Water boiler consisting of a housing suspended on a columnar supporting structure, inside which an oven chamber and a convective shaft are formed, with heat exchange screens made of gas-tight membrane elements between the housing and the furnace chamber, and heat exchange screens mounted to the heat exchange screens. burners, wherein horizontally oriented convective packages are arranged above each other in a convective shaft and above them a gas channel is characterized in that the convective packages (7) are self-supporting, constructed of membrane panels. and there are at least three, and the burners (5) are four 'or six pieces, arranged opposite F on two levels, respectively bottom row - at height-''* at = 1/3 H bp. and top row h _rr = 1/2 H bp, where H bp. is the height of the furnace chamber (4), whereby the burners (5) are tilted down at an angle of 5 to 12 °. Water boiler according to claim 1, characterized in that the burners (5) are six and are arranged on two levels in horizontal lines, respectively, in three pieces on opposite screens. Water boiler according to claim 1, characterized in that the burners (5) are six and are staggered three on a screen such that a high-pressure burner (5) is located on one level against a low-level burner (5). . Water boiler according to claim 1, characterized in that the burners (5) are four, diametrically located on opposite screens, such as the angle of inclination β of the burners (5) along the horizontal axis of the boiler towards the center of the furnace chamber (4). varies from 0 to 12 °.