RU112985U1 - BOILER - Google Patents

Abstract

1. A heating boiler for heating residential and industrial premises, containing a body in the form of a water jacket, framing the furnace and gas duct spaces, and partitions installed in the gas duct space, in the form of hollow flat heat exchange elements communicated with the cavity of the jacket and located opposite to each other at different heights levels with overlapping each other in the gas duct with the formation of a labyrinth gas channel, characterized in that a convective bundle of pipes is installed in the upper part of the boiler, and grate bars are installed in the lower part of the boiler, made of heat-resistant pipes, which make up a single circuit with a water jacket, while the boiler contains three heat exchange elements, of which the upper and lower heat exchange elements are installed on the rear wall of the housing perpendicular to its surface, and the middle heat exchange element is installed on the front wall of the housing between them and with a deviation of 15º downward relative to the horizontal axis of the boiler, while the rear wallthe boiler is designed with an inclination towards the inside of the boiler, with a deviation from the vertical axis of the boiler by 15º. ! 2. Heating boiler according to claim 1, characterized in that the heat exchange elements are made in width equal in size to the mating inner side of the boiler. ! 3. Heating boiler according to claim 1, characterized in that hatches for cleaning the boiler are located on the front wall of the boiler.

Description

The utility model relates to heat engineering and can be used for heating residential and industrial premises, other buildings with an area of up to 1500 m2.

Heating boilers are known in which to increase the area of convective heat transfer in the cavity of the boiler, obstacles are placed in the way of the flow of gaseous products of fuel combustion, which are described below.

A heating boiler is known, comprising a housing, the front, rear and side walls of which are formed with a combustion device installed in it, a sectional heat exchanger connected to distributing and collecting manifolds, gas ducts connected to the outlet of the housing for domestic purposes with the capacity of water for providing labyrinth movement of the combustion furnaces gases, characterized in that it further comprises at least three horizontally located in the body of the partition, two of which are installed with the possibility of transition The passage of flue gas to the front and side walls of the casing, and the third located between them, with the possibility of blocking the passage of flue gases to the rear and side walls, the exit from the casing connecting the flues is located in its upper part, and the number of flues in it is at least three. The boiler further comprises at least one heating element located in the heat exchanger (RF patent No. 2109223).

The disadvantages of such a boiler are the insufficient use of heat from the exhaust gases and, as a consequence, the high temperature of the exhaust flue gases at the outlet of the boiler; insufficient flue gas turnover and insufficient turbulization of the gas flow, as well as significant entrainment of solid particles with flue gases, in addition, compared to the dimensions of the boiler, the surface of the heating of the boiler is small. Thus, the heat of the combustion products of the fuel is not used effectively and therefore the efficiency of the boiler is low.

A heating boiler is known, comprising a casing in the form of a water jacket framing the furnace and flue spaces, with flat hollow heat-exchange elements inserted horizontally at different heights inserted horizontally at different heights, forming a closed coolant circuit with the cavity of the water jacket, and also forming in the flue space labyrinth gas channel, in this case n = N / 10 + 1 of the aforementioned flat hollow heat-exchange elements are introduced into the internal cavity of the boiler, and a hatch into the framing shirt s, corresponding to the number of installed transverse heat exchange elements, the heat exchange elements being longitudinal and transverse and installed symmetrically to the axis of the transverse internal section of the boiler, and each subsequent one is rotated relative to the previous one by an angle of 90 °, and their end sides are connected to opposite sides of the framing shirt and form a closed loop circulation of the heat transfer medium, while between the side surfaces of the heat exchange elements on both sides and the inner surface of the sample For the amalgamation jacket, openings with a cross section S = 0.9-1.1 (35 + 1.5N) cm ^{2 were made} for the passage of gaseous products of fuel combustion, and hatches with covers and heat reflectors were installed against the transverse heat exchange elements, where N is the boiler power , kW, n is the number of flat hollow heat-exchange elements, taken as a rounded integer; k is the number of hatches equal to the number of transverse heat exchange elements (RF patent No. 2232948).

The disadvantages of this boiler is that it is quite complex structurally and works only on a gas-air mixture, which may not always be convenient for users. In addition, there is practically no flue gas turnover, almost direct upward flow of exhaust gases and their high temperature at the outlet, as well as in the fuel combustion zone, where the highest temperature, there are no heat exchange elements, only convective heat of the gas-air mixture is used.

The closest in technical essence and the achieved technical result is a heating boiler (RF patent No. 2122688) containing a casing in the form of a water jacket framing the firebox and gas duct, equipped with 2-4 hollow partitions installed horizontally and diametrically opposite at different heights with overlapping each other in the duct and communicated with the cavity of the shirt and forming a labyrinth gas channel in the duct. In this design of the boiler, the built-in heat-exchange elements allow to increase the heat-exchange surface of the heating of the boiler, the capacity of the boiler, which helps to increase its efficiency.

However, a simple increase in the number of horizontal heat exchange elements of more than two leads to insignificant turbulization of the flow of gaseous products of fuel combustion and a slight increase in efficiency, which is economically and technically not rational, and also helps to reduce the temperature of the exhaust gases, which leads to the formation of condensate and worsen the conditions for soot removal from horizontal surfaces of heat exchange elements. In addition, a small combustion chamber for burning solid fuel, small doors for cleaning create inconvenience in the operation of the boiler.

The objective of this utility model is to increase the efficiency of the boiler due to the intensification of heat transfer in a heating boiler designed to heat individual houses and other buildings up to 1,500 m2, to prepare hot water for household needs, as well as the convenience of maintaining the boiler and reducing fuel consumption.

The essence of the utility model lies in the fact that in a heating boiler for heating residential and industrial premises, which contains a casing in the form of a water jacket framing the furnace and flue spaces, and partitions installed in the flue space, in the form of hollow flat heat-exchange elements communicated with the cavity of the shirt and located opposite to each other at different altitude levels with overlapping each other in the gas duct with the formation of a labyrinth gas channel, according to a utility model, in the upper part of the boiler a convective bundle of pipes has been updated, and grates made of heat-resistant pipes are installed in the lower part of the boiler, which make up a single circuit with a water jacket, and the boiler contains three heat-exchange elements, of which the upper and lower heat-exchange elements are installed on the rear wall of the housing perpendicular to its surface, and the middle heat-exchange element is installed on the front wall of the housing between them and with a deviation of 15 degrees down, relative to the horizontal axis of the boiler, while the rear wall of the boiler is made with a slope prefecture inside the boiler, with a deviation from the vertical axis of the boiler 15 degrees.

The heat exchange elements of the heating boiler are made equally wide in width with the mating inside of the boiler

A convective tube bundle is located at the top of the boiler.

Hatches for cleaning the boiler are located on the front wall of the boiler. Common salient features with the prototype are:

- the boiler body is made in the form of a water jacket framing the furnace and flue spaces,

- partitions are installed in the gas duct space in the form of hollow flat heat-exchange elements communicated with the cavity of the shirt;

- partitions in the form of hollow flat heat-exchange elements are located opposite each other at different altitude levels with overlapping each other in the duct with the formation of the labyrinth gas channel.

The essential features that distinguish a utility model from a prototype are the following:

- a convective bundle of pipes is installed in the upper part of the boiler;

- grates made of heat-resistant pipes, which make up a single circuit with a water jacket, are installed in the lower part of the boiler;

- the boiler contains three heat exchange elements, of which

* the upper and lower heat exchange elements are mounted on the rear wall of the housing perpendicular to its surface,

* the middle heat-exchange element is installed on the front wall of the housing between them and with a deviation of 15 degrees down, relative to the horizontal axis of the boiler,

* the back wall of the boiler is inclined inside the boiler, with a deviation from the vertical axis of the boiler of 15 degrees.

The inventive utility model is industrially applicable and can be used in the industrial production of heating boilers for heating residential and industrial premises.

Based on the results of the patent search, the applicant believes that the claimed utility model meets the condition of patentability "novelty", since the boiler is not known from the prior art, which is characterized by all the essential features of the claimed utility model.

The boiler is always executed with only three heat exchange elements, and the size of the boiler affects its power.

The introduction of a convective bundle of pipes into the cavity of the boiler allows you to increase the heat transfer surface of the heating between the heat-transfer medium and flue gases, as well as make the most of the heat of the exhaust gases and lower their temperature at the outlet of the boiler.

The introduction of grates to the water jacket allows you to enhance the heating of the coolant and reduce the heating time of the coolant in the boiler due to the fact that the grates are in the fuel combustion zone. There is an increase in the rate of circulation of the coolant, both inside the boiler itself and in the heating system, in which the heating devices warm up very quickly from the moment the boiler starts to work.

The inclined arrangement of the rear wall of the boiler at an angle of 15 degrees allows you to maximize the use of the temperature of the fuel in the combustion zone, and the heat of the exhaust gases. The rear wall of the boiler, located at an angle of 15 degrees, “clamps” the flame at the locations of the heat-exchange elements and a high-temperature zone is created.

The mutual arrangement of the heat exchange elements allows to extend the gas duct, to ensure the labyrinth movement of flue gases, to create turbulence in gas flows, to ensure uniform heating of the heat carrier in the heat exchange elements.

Thus, the introduction of a new design of the heating boiler allows to intensify the heat transfer process.

The invention is illustrated in the drawing, which shows a longitudinal section of the boiler. The positions in the drawing indicate:

1 - combustion chamber;

2 - furnace door;

3 - upward flow of flue gases;

4 - heat exchange elements;

5 - water shirt;

6 - chimney;

7 - grate;

8 - inlet pipe of the coolant;

9 - convective bundle of pipes;

10 - output pipe coolant;

11 - blew;

12 - hatches for cleaning the boiler;

13 - the front wall of the boiler;

14 - back wall of the boiler.

To improve the technical parameters and properties of the heat transfer process, the following elements are introduced into the boiler: over the blower 11, grates 7 are made of heat-resistant pipes, forming with the water jacket 5 a closed circulation circuit of the coolant, hollow flat heat-exchange elements 4 filled with coolant, one of which is located under 15 degrees to the front wall of the boiler 13, two others perpendicular to the rear wall of the boiler 14, which is tilted at an angle of 15 degrees with respect to the vertical axis of the boiler ; convective bundle of pipes, which is a single contour of the coolant medium 5.

The location of the heat exchange elements and the introduction of a convective bundle of pipes allows the most efficient use of the heat of the exhaust gases due to the fact that the path of their passage is lengthened, their cooling is achieved by washing a larger heat transfer surface and increasing the turbulence of the ascending flue gas flows.

The introduction of grate-irons from heat-resistant pipes into the boiler design, which form a single coolant circuit with the boiler’s water jacket, improves the conditions of circulation of the coolant due to its uniform distribution, fast heating rate, and at the same time they are an additional heating surface.

The heating boiler operates as follows: the coolant is supplied through the inlet pipe 8 into the cavity of the water jacket 5. In the furnace space 1, where the grates are located 7, the fuel is burned. The heat obtained from the combustion of fuel heats the grid-irons that are in the combustion zone of the fuel, then, moving in the labyrinth gas duct, the combustion products of the fuel 3 “wash” the heat exchange elements 4, the inner wall of the boiler and the convective bundle 9, come in contact with the heat exchange surfaces 4, 9, heating the heat-transfer medium, transfer to them the bulk of the thermal energy and go into the chimney 6. The most efficient heat transfer occurs in the heat exchange elements 4 of the front 13 and rear 14 of the boiler walls, in the grates 7, in the attractive beam 9, as well as in the boiler’s water jacket, due to the inclined arrangement of the rear wall of the boiler 14. The heat carrier enclosed in them is subjected to intense heating and rapid thermal expansion due to its small volume, as a result of which a directed flow of heat carrier motion is created, increasing its circulation velocity in the heating system by increasing the pressure difference at the inlet 8 and outlet 10 of the boiler. If necessary, the boiler is cleaned from soot without stopping the boiler through the hatches 12 located on the front wall.

The technical result of the utility model is to increase the efficiency of the heating boiler due to the intensification of heat transfer from the upward flow of combustion products. The new arrangement of heat exchange elements in the boiler allows to increase the efficiency and intensity of heat transfer from the upward flow of fuel combustion products to the heat-transfer medium and increase its circulation rate in the heating system by increasing the pressure difference at the inlet and outlet of the boiler. Using an industrial design of the claimed design can reduce fuel consumption and reduce environmental pollution.

An increase in the efficiency of a heating boiler has been proved under experimental conditions, experimentally, during three heating seasons at enterprises in the Far Eastern region ..

When the heating season passed at the enterprises “Slavyansk ATP”, “Khorol ATP”, ZAO “Fadeevskoye” and Baza LLC PKF “Amur”, where the boiler was experimentally tested, the fuel consumption analysis for the whole winter period was carried out. Fuel consumption when using the inventive industrial design decreased from 41.5% to 50%. The boiler is simple and easy to maintain.

The table shows the results for the heating period (from October to April) 2010

Company Fuel consumption before installing a heating boiler, t Fuel consumption after installing the boiler, Fuel economy, t t % Slavic ATP 220 120 54 one hundred Khorol ATP 400 166 41.5 250 Base OPKF "Amur" 120 fifty 41.7 70 CJSC Fadeevskoye 60 thirty 50,0 thirty

Claims (3)

1. A heating boiler for heating residential and industrial premises, comprising a casing in the form of a water jacket framing the furnace and flue spaces, and partitions installed in the flue, in the form of hollow flat heat-exchange elements communicated with the cavity of the shirt and located opposite to each other at different heights levels with overlapping each other in the flue with the formation of a labyrinth gas channel, characterized in that in the upper part of the boiler there is a convective bundle of pipes, and in the lower part The grates are installed made of heat-resistant pipes, which form a single circuit with a water jacket, while the boiler contains three heat-exchange elements, of which the upper and lower heat-exchange elements are installed perpendicular to its surface on the rear wall of the casing, and the middle heat-exchange element is installed on the front wall case between them and with a deviation of 15º downward relative to the horizontal axis of the boiler, while the rear wall of the boiler is made inclined inside the boiler, with a deviation from the vertical axis of the boiler n a 15º. 2. The heating boiler according to claim 1, characterized in that the heat exchange elements are made equally wide in width with the mating inside of the boiler. 3. The heating boiler according to claim 1, characterized in that hatches for cleaning the boiler are located on the front wall of the boiler.