RU87243U1 - BOILER - Google Patents

Abstract

1. A boiler containing a firebox, a water jacket, a convective gas duct, an ash pan, grates, inlet and outlet channels for the coolant, a loading furnace door, a door for removing products remaining after burning fuel, characterized in that the water jacket is made entirely covering the furnace. ! 2. The boiler according to claim 1, characterized in that it further comprises a second water jacket, covering the first on the sides, while a convective gas duct is placed between the first and second water jackets, while both the upper and lower parts of the thermal jackets are made common. ! 3. The boiler according to claim 1, characterized in that the furnace has additionally placed arcuate pipes, the internal cavities of which are connected to the internal cavity of the lower part of the water jacket, while the internal cavities of the arcuate pipes at the inflection points are connected to the internal cavity of the upper part of the water jacket. ! 4. The boiler according to claim 1, characterized in that in the furnace from the side opposite to the side on which the loading furnace door is located, pipes are additionally placed through which the internal cavity of the lower part of the water jacket is connected to the internal cavity of the side part of the water jacket. ! 5. The boiler according to claim 1, characterized in that the grate is made in the form of tubes, the inner cavity of each of which is connected at both ends to the inner cavity of the lower part of the water jacket. ! 6. The boiler according to claim 1, characterized in that in the convection duct there are additionally heat receivers made, for example, of pipes, the internal cavities of which are connected to the internal cavity by at least one water jacket. ! 7. The boiler according to claim 1, characterized in that �

Description

The proposed utility model relates to boiler building and can be used for heating greenhouses, cottages, cottages, hangars, warehouses, etc., while it can be used as solid (wood, wood waste, cardboard products, coal, etc.), and liquid (fuel oil, diesel fuel, etc.) or gaseous (propane, butane, etc.) types of fuel.

A boiler is known that contains a central firebox with burners and a radiation heating surface in the form of pipes arranged to form a spherical surface (see USSR Author's Certificate No. 129073, class F23M 5/08, 1969).

The disadvantage of this boiler is its low profitability due to the significant aerodynamic drag of the gas path, increased heat loss to the environment through the walls of the boiler and the low proportion of heat taken into the furnace, as well as due to significant suction of cold air into the furnace.

A boiler is known that contains a central furnace with burners, the closed volume of the radiation chamber of which is formed by the ends of the blocks enclosed in gas-tight shells with tubular coils located in the gaps between them, while the end face of at least one of the blocks is equipped with a removable bottom adjacent to the stops mounted on the inner the shell on the side of the radiation chamber and secured in the said shell using the clamping device, and the cavity of the removable bottom is connected to the tubular coils (see RF Patent No. 2059158 Cl. F23M 5/08, 1996).

The disadvantage of this boiler is its low efficiency.

The closest in technical essence to the proposed one is the KS-TG boiler, which contains a furnace, a water jacket, a convective gas duct, an ash pan, grate, water channels, a loading furnace door, and a door for removing products left after burning fuel (see D.Ya. Borshchov Cast iron and steel heating boilers. Reference manual. M. Energoatomizdat. 1992, p.40, fig. 13).

The disadvantage of this boiler is its low efficiency, since heat is removed only from a small part of the radiation surface.

The purpose of this utility model is to increase efficiency.

This goal is achieved by the fact that in a boiler containing a firebox, a water jacket, a convective flue, an ash pan, grates, inlet and outlet channels for the coolant, a loading door, a door for removing products remaining after burning fuel, the water jacket is made entirely covering the furnace, when this boiler may contain a second water jacket, covering the first on the sides, while the convective duct is located between the first and second water jackets, while in the furnace can be additionally sized arc-shaped pipes whose internal cavities are connected to the internal cavity of the lower part of the water jacket are provided, while the internal cavities of the arcuate pipes at the inflection points are connected to the internal cavity of the upper part of the water jacket, while in the furnace from the side opposite to the side where the loading furnace door is located, can be additionally placed tubes through which the inner cavity of the lower part of the water jacket is connected with the inner cavity of the side of the water jacket, while the grates can be Execute as tubes, the inner cavity of each of which through both ends connected with the interior bottom of the water jacket, wherein in the convection duct for increasing the efficiency of the boiler can be set additional heat sink, such as a pipe connected to the water jacket

Figure 1 presents the proposed boiler - front view; figure 2 - boiler in cross section; figure 3 - placement in the furnace of additional pipes; in Fig 4 - one of the possible schemes of convective gas duct with a two-inlet.

The boiler is an all-welded structure consisting of a furnace 1, a water jacket 2, a convective gas duct 3, an ash pan 4. In the lower part of the furnace there are grate 5 made in the form of tubes, the internal cavity of each of which is connected through both ends to the internal cavity of the lower part of the water shirts. On the front of the boiler there is a loading furnace door 6 and door 7 for removing products left after fuel combustion, as well as doors 8 for cleaning the convective gas duct (reflectors and thermal insulation are installed on the inside of the doors, providing a standard temperature on the outer surface, - in the drawing not shown). A number of arcuate pipes 9 are additionally placed in the furnace 1, the internal cavities of which are connected to the internal cavity of the lower part of the water jacket 2, while the internal cavities of the pipes 9 at the inflection points are connected directly or through the pipe 10 to the internal cavity of the upper part of the water jacket 2. In the furnace, from the side opposite to the side in which the loading furnace door 6 is placed, pipes 11 are placed through which the inner cavity of the lower part of the water jacket 2 is connected with its inner cavity of the side part. The boiler further comprises a second water jacket 12, covering the first 2 from the sides, while the convection duct is located between the water jackets 2 and 12 and has inlets 13 and 14, while both the upper and lower parts of the thermal jackets are made common. In addition, the boiler has a supply 15 and outlet 16 channels for the coolant. The inlet channel 15 is connected to the lower part of the water jackets 2 and 12, and the outlet 16 to the upper part thereof. On the outside, the boiler is covered with insulating material, for example, mineral wool, glass wool, asbestos, brick, etc. - not shown in the drawing. To avoid warpage of the structure in water jackets 2 and 12, stiffeners must be installed - not shown in the drawing. The drawing also does not show the burners that are necessary when using liquid and gaseous fuels. In the convection duct to increase the efficiency of the boiler, additional heat sinks can be installed, for example, in the form of pipes connected to water jackets (not shown in the drawing).

The boiler operates as follows.

When burning fuel (for its ignition, an additional pressurization system can be used - not shown in the drawing), its heat acts on the walls of the water jackets 2 and 12. Also, the walls of the water jackets 2 and 12 are affected by heat from the fuel gases passing through the gas duct 3. In addition, heat is taken away by pipes 9 and 11, as well as by pipes placed in the convective duct 3 (not shown in the drawing). Due to the coverage of the furnace 1 with a water jacket 2, additional heat removal by pipes 9 and 11, as well as heat removal from the gas duct 3, high installation efficiency is achieved. At the same time, the maximum efficiency of the boiler with ensuring its stable operation is achieved with the following size ratios: width at the bottom of water jackets - 450-650 mm, width at the top of water jackets - 350-450 mm, length - 550-750 mm, height - 400 -550 mm.

The high efficiency of the proposed boiler is the advantage and advantage of this technical solution compared to the prototype.

Claims (7)

1. A boiler containing a firebox, a water jacket, a convective gas duct, an ash pan, grates, inlet and outlet channels for the coolant, a loading furnace door, a door for removing products remaining after burning fuel, characterized in that the water jacket is made entirely covering the furnace. 2. The boiler according to claim 1, characterized in that it further comprises a second water jacket, covering the first on the sides, while a convective gas duct is placed between the first and second water jackets, while both the upper and lower parts of the thermal jackets are made common. 3. The boiler according to claim 1, characterized in that the furnace has additionally placed arcuate pipes, the internal cavities of which are connected to the internal cavity of the lower part of the water jacket, while the internal cavities of the arcuate pipes at the inflection points are connected to the internal cavity of the upper part of the water jacket. 4. The boiler according to claim 1, characterized in that in the furnace from the side opposite to the side on which the loading furnace door is located, pipes are additionally placed through which the internal cavity of the lower part of the water jacket is connected to the internal cavity of the side part of the water jacket. 5. The boiler according to claim 1, characterized in that the grate is made in the form of tubes, the inner cavity of each of which is connected at both ends to the inner cavity of the lower part of the water jacket. 6. The boiler according to claim 1, characterized in that in the convection duct there are additionally heat receivers made, for example, of pipes, the internal cavities of which are connected to the internal cavity by at least one water jacket. 7. The boiler according to claim 1, characterized in that the grates are made in the form of tubes, the inner cavity of each of which is connected at both ends to the inner cavity of the lower part of the water jacket.