RU151387U1 - WATER BOILER RECTANGULAR CROSS-SECTION - Google Patents

Abstract

The boiler is of a rectangular rectangular cross-section, including a foundation on which a firebox and convection unit are mounted, while the firebox space, respectively, from below, from the front, from the sides and from the top is limited by an inclined repulsive furnace grate, front, side and ceiling furnace screens made in the form of tube panels, hydraulically connected with the corresponding two upper and two lower longitudinal collectors of the boiler, the furnace adjacent to the convection unit, including convective flues, lined with heat exchange surfaces containing transversely streamlined tube bundles of the corridor arrangement, hydraulically connected to the longitudinal collectors of the boiler, characterized in that it is additionally equipped with a precipitation chamber, while the boiler foundation is made as a single support foundation frame including an inclined repulse furnace grate body and a precipitation chamber case, moreover, the furnace body and convection unit are supported on a single support foundation frame and fastened with it, while both the upper and lower rodolnye collectors boiler are designed as a single element of the furnace and convective block.

Description

The utility model relates to boiler equipment, in particular to low-power boilers with a heating capacity of up to 4.0 MW with a combustion device in the form of an inclined overflow grill, can be used in heating systems of industrial and residential buildings.

Currently, in the practice of Russian boiler building, a tendency is being developed for the monoblock supply of boilers and furnace devices to the facility, which significantly speeds up the installation work and reduces construction costs.

In this case, the casing of the furnace devices of various designs and their frame bases are used as the direct foundation of the furnace of the boiler (see Hephaestus boilers: JSC "Biysk boiler plant") with a screwing bar, while the convection block of the boilers is supported by independent support posts. For these purposes, boilers with a rectangular firebox formed by two lower longitudinal collectors, on which the vertical side screens of the firebox, and the vertical risers of the convection part of the boiler are closed, are being developed.

Also known is a boiler of a rectangular rectangular cross-section, including a foundation on which a furnace and convection unit are mounted, while the furnace space, respectively, from below, from the front, from the sides and from above, is limited by an inclined repulsive furnace grate, front, side and ceiling furnace screens made in the form of tube panels hydraulically connected with the corresponding two upper and two lower longitudinal collectors of the boiler, the furnace adjacent to the convection unit including convection regular gas ducts equipped with heat exchange surfaces containing transversely streamlined tube bundles of the corridor arrangement hydraulically connected to the longitudinal collectors of the boiler (see Gusev Yu.L. Basics of designing boiler plants, M - 1967, pp. 87-90, Fig. II .41. )

The disadvantage of this solution is the impossibility of transporting the boiler as a single unit, in addition, when using furnace devices in the form of forward gratings or an inclined overtaking grate, the manufacture of the boiler together with the furnace in the form of a single unit becomes difficult.

The task to be solved by the claimed invention is directed, is to provide the possibility of transporting the boiler in the form of a single transportable unit of high availability for work.

The technical result obtained when solving the problem is expressed in reducing the weight and size characteristics of the boiler, reducing the amount of installation work (there is no need to equip the foundation) and, as a result, construction costs.

To solve this problem, the boiler is of a rectangular rectangular cross-section, including a foundation on which the furnace and convection unit are mounted, while the furnace space, respectively, from below, in front, from the sides and from above, is limited by an inclined repulsive furnace grate, front, side and ceiling furnace screens made in the form of tube panels hydraulically connected with the corresponding two upper and two lower longitudinal collectors of the boiler, the furnace adjacent to the convection unit, including for convective gas ducts equipped with heat-exchange surfaces containing transversely streamlined tube bundles of the corridor arrangement, hydraulically connected to the longitudinal collectors of the boiler, characterized in that it is additionally equipped with a settling chamber, while the boiler foundation is made as a single supporting foundation frame including an inclined repulsive furnace grate and the case of the precipitation chamber, and the body of the furnace and the convection unit are supported on a single support foundation frame, and fastened with it, p and that both the upper and lower longitudinal manifolds formed as single boiler furnace and convection elements of block.

A comparative analysis of the features of the claimed solution with the signs of the prototype and analogues indicates the conformity of the claimed solution to the criterion of "novelty."

The distinguishing features of the utility model provide the solution to the following functional tasks.

A sign indicating that the boiler is "additionally equipped with a precipitation chamber" contributes to the release of exhaust gases from ash particles.

Signs indicating that "the boiler’s foundation is made as a single supporting foundation frame, including the inclined overflow furnace lattice body and the precipitation chamber case" provide the possibility of using the named functional elements of the boiler as structural elements of its foundation.

Signs indicating that “the furnace body and the convection unit are supported by a single support foundation frame and are attached to it” allow “combining” the functional elements of the boiler into one spatial structural unit.

Signs indicating that “both the upper and lower longitudinal collectors of the boiler are made as single elements of the furnace and convection unit” allow the foundation of the boiler to be formed by combining the furnace body (installed on its own base) and a precipitation chamber in one structural block. This design of the foundation of the boiler can be applied to various types of furnace devices (back-up grilles, screwing rail, inclined overflow grille).

In FIG. 1 shows a longitudinal vertical section through a boiler; in FIG. 2 shows a horizontal longitudinal section AA of a convection unit.

The drawings show the foundation 1, the housing 2 and the base 3 of the inclined pusher grill, a precipitation chamber 4, a furnace 5, a convection unit 6, a front 7, side 8 and a ceiling 9 furnace screens, the upper 10 and 11 and lower 12 and 13 longitudinal collectors of the boiler, radiant convective gas duct 14, the first fin tubular panel 15, tubular transverse connections 16 and 17, their ends 18, longitudinal horizontal pipes 19, vertical pipes 20, transverse manifold 21, radiant convective assembly 22, expansion chamber 23, ash reception chamber 24 second fin tr sponge panel 25, windows 26, door 27.

A furnace 5 mounted on it is supported on the foundation 1 (above the housing 2 of the inclined pusher) and the convection unit 6 (above the housing of the precipitation chamber 4). The space of the furnace 5, respectively, from below, from the front, from the sides and from above, is limited by an inclined repulsive furnace grate, front 7, side 8 and ceiling 9 furnace screens made in the form of tube panels hydraulically connected to the corresponding two upper 10 and 11 and two lower 12 and 13 longitudinal boiler manifolds. The furnace 5 is directly adjacent to the radiant-convection unit 22 of the convective block 6 containing the radiant-convective gas duct 14. Thus, the trailing edge of the furnace 5 is represented by the first fin tubular panel 15 of the convective block 6 (one side faces the cavity of the furnace). The radiant convective gas duct 14 is equipped with heat exchange surfaces containing transversely streamlined tube bundles of the corridor arrangement, hydraulically connected to the corresponding longitudinal collectors of the boiler.

Side 8 furnace screens are made in the form of tube panels hydraulically connected with the corresponding upper (10 and 11) and lower (12 and 13) longitudinal collectors of the boiler, with the possibility of successive upward and downward movement of water along them, while the vertical pipes are installed first in the screens 20 having a larger diameter pipe tube panels.

Both the upper (10 and 11) and lower (12 and 13) longitudinal collectors of the boiler are made as single elements of the furnace 5 and convection unit 6, with the possibility of their use as load-bearing beams with a length corresponding to the length of the boiler.

The ceiling furnace screen 9 includes tubular transverse connections 16 and 17, the ends 18 of which are fastened to the upper longitudinal collectors 10 and 11 without hydraulic connection with them, while the cavity of the transverse connections 16 and 17 are communicated with each other by a tubular panel containing longitudinal horizontal pipes 19, the ends of which are open in them.

The front furnace screen 7 (boiler) is made in the form of a panel of vertical pipes with a diameter equal to the diameter of the pipes of the ceiling screen 9. In this case, the upper ends pass into the horizontal ceiling panel and communicate with the cavity of the front tubular transverse connection 16, and the lower ones are connected with the transverse collector 21 of the front furnace screen 7.

A feature of a furnace device equipped with an inclined repulsive grill is the creation of a significant amount of small fractions of fuel (as a result of grinding it with movable and fixed grates), which leads to a significant increase in ash removal of flue gases in comparison with other types of furnace devices.

To reduce the likelihood of a skid of the heating surface of the convective unit containing the radiant-convective gas duct 14, a preliminary deposition of fly ash is provided, which is provided by the radiant-convective assembly 22 and an expansion chamber 23, under which a precipitation chamber 4 is placed, below which there is a receiving chamber of ash and slag 24, made with the possibility of removing ash from it together with slag into the ash channel. The radiant-convection unit 22 of the convection unit 6 is limited along the axis of the boiler by fin panels 15 and 25, provided with corresponding side openings (windows 26) for the passage of gases.

To control the possible loss of ash in the radiant-convection unit 22 and, if necessary, clean its lower zone, use the door 27.

The claimed device operates as follows.

The boiler is mounted in one assembly, including the foundation 1 (combining, the housing 2 and the supporting base 3 of the inclined pusher grating and the casing of the precipitation chamber 4. On the foundation 1, the boiler is fixed, which consists of the furnace 5 and the convection unit 6, the remaining components and assemblies necessary for boiler operation, connect it to the water source and consumers of hot water supply .. The combustion of fuel is carried out in a known manner in the furnace 5.

Flue gases containing ash particles in their volume from the furnace 5 space enter the radiant-convection unit 22 of the convective unit 6 (through the window 26 on the side of the first fin tubular panel 15). The radiant-convective gas duct 14 provides (due to the intense radiant-convective heat transfer) cooling of flue gases and, as a result, their volume reduction, and, as a result, a decrease in the gas velocity. At the exit of the radiant-convection unit 22, an expansion chamber 23 is located outside the window of the second fin tubular panel 25, in which, as a result of a sharp drop in the speed of the flue gases, the bulk of the fly ash is intensively deposited, which is deposited in the ash receiving chamber 24, from where it is removed as it accumulates through the butterfly valve to the ash channel.

In the process of moving gases, the latter give their heat to the water pumped through the heat-removing elements of the boiler.

In this case, the water in the heat-removing elements moves as follows: it enters through the water inlet to the boiler (indicated by the arrow of the water inlet in the drawing), then it enters the cavity of the rear transverse connection 17, then through the longitudinal horizontal pipes 19 of the ceiling screen 9 enters the cavity of the front transverse connection 16, through the pipes of the front screen 7 enters its lower transverse collector 21; then two streams enter the vertical pipes 20 of the side shields 8, in which the washers are installed in the upper sections (not shown in the drawings), which determines the direction of the main water flow into them in the lower longitudinal collectors 12, 13 of the furnace shields 8, in which the water is two symmetrical streams makes lifting and lowering movements in sections formed by vertical pipe panels. Next, the water enters the convection unit 6, where it makes a series of lifting and lowering movements in the transversely streamlined tube bundles, and through the upper transverse rectilinear collector at the rear front of the boiler (not indicated in the drawings) located at the rear front of the boiler, is directed by the combined flow to the upper pipe collector 10 or 11, designed to exit the heated water from the boiler.

Mechanical cleaning of the pipe surfaces of convective flues is carried out through the door 27. Removing slag from the furnace and ash deposited in the radiant-convective flues 14 can be carried out in various ways, depending on the design of the combustion device. In this technical solution, slag is discharged into the ash removal channel (not indicated in the drawings). The cleaning of the convection ducts of block 6 is carried out by installing the corresponding cleaning door on the side surface similarly to the door 27.

The vertical pipes constituting the tube bundles of the convection unit 6 are of the same length and do not require individual patterns. Also, the length of the horizontal tubular cross-links 16 and 17 (upper and lower) is the same. This allows you to rationally use the volume of convective flues, and also simplifies the manufacture of convective block 6.

Claims (1)

The boiler is of a rectangular rectangular cross-section, including a foundation on which a firebox and convection unit are mounted, while the firebox space, respectively, from below, from the front, from the sides and from the top is limited by an inclined repulsive furnace grate, front, side and ceiling furnace screens made in the form of tube panels, hydraulically connected with the corresponding two upper and two lower longitudinal collectors of the boiler, the furnace adjacent to the convection unit, including convective flues, lined with heat exchange surfaces containing transversely streamlined tube bundles of the corridor arrangement, hydraulically connected to the longitudinal collectors of the boiler, characterized in that it is additionally equipped with a precipitation chamber, while the boiler foundation is made as a single support foundation frame including an inclined repulse furnace grate body and a precipitation chamber case, moreover, the furnace body and convection unit are supported on a single support foundation frame and fastened with it, while both the upper and lower rodolnye collectors boiler are designed as a single element of the furnace and convective block.

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