RU2806540C1 - Metal furnace - Google Patents

Abstract

FIELD: heat engineering.

SUBSTANCE: metal furnace firebox contains walls that form a combustion chamber and at least one heat recovery unit located in it. The heat recovery unit includes a set of lamellas fixed at their ends in support posts, indented from the firebox wall and inclined towards it, forming slots between themselves for passage of flame and flue gases to the firebox wall. The lamellas are inclined against the horizon and are grouped between the support posts in two mirror-symmetrical rows, forming a herringbone pattern with the apex pointing upward. In this case, the support racks are welded to the inner surface of the firebox wall.

EFFECT: improved efficiency.

7 cl, 5 dwg

Description

Field of technology to which the invention relates

The invention relates to the field of heating engineering, namely to the designs of household stoves and fireplaces, mainly sauna stoves.

State of the art

A steel stove for Russian baths and Finnish saunas is known (see patent RU 68099, IPC: F24B 9/00, publ. 11/10/2007), containing a welded steel firebox with a removable grate and a blower door, a water tank, a heater surrounded by slotted chimneys , communicating with the firebox, and a pipe. To protect against deformation and burnout, the steel walls of the firebox are tightly lined with refractory bricks from the inside. However, this method of protecting the walls of the firebox can only be used for large furnaces.

A bath stove is known (see patent RU 164926, IPC: F24B 5/02, publ. 09/27/2016), containing a firebox with a door and a hole for the chimney, a frame enclosing the firebox made of a heat-accumulating load held by a metal grate, a screen placed between them in the form metal sheet with slots and stamped ribs, protecting the walls of the firebox from the deforming effect of the heat-accumulating load stones during expansion during furnace operation. The disadvantages of this design include the likelihood of rapid destruction (burnout) under the influence of high thermal loads of such weak points of the firebox as corners, welds, etc. At the same time, there is a danger of working with the furnace door, through which flames appear when it is opened trying to get out.

As the closest analogue, in terms of the presence of features similar to the essential features of the proposed technical solution, the design of a metal firebox placed in a wood-burning fireplace was adopted, see patent FR 2458029, IPC: F24B 1/188, F24B 9/04, publ. 12/26/1980

As you know, a fireplace is one of the types of household stoves. According to the drawings and materials describing the patent FR 2458029, the fireplace contains a metal firebox, the walls of which form the volume of the combustion chamber where fuel is burned. The combustion chamber contains a recovery unit that provides heat extraction and includes inclined metal blades fixed at their ends in a frame behind which liquid circulates in pipes.

Inclined metal blades are thin plates placed in a row, i.e. in the form of an ordered structure such as blinds, and therefore the term “slats” can be applied to them, which more accurately conveys the functions of these elements than the term “blades”, usually used for moving elements.

As can be seen from the drawings for patent FR 2458029, the frame is made in the form of vertical rod elements - then rack-holders, in which blades (lamellas) are fixed at the ends, indented from the firebox wall and inclined towards it, which ensures the formation of gaps between them for passage flames and hot flue gases to the wall of the furnace.

These features of the closest analogue are similar to the essential features of the claimed device.

The advantages of the known design include the increased heat capacity of the furnace and the effective utilization of flue gases and generated heat, which do not go directly into the chimney, but are captured by blades (lamellas) and redirected to the walls of the firebox, where heat is accumulated, increasing the efficiency of the furnace.

The disadvantages of the closest analogue include the fact that the flame and hot gases breaking through the holes between the lamellas to the walls of the firebox spread over the entire inner surface of the walls, capturing the corner zones of the firebox, which are known to be weak points due to the presence of welding elements in them. seams and/or bending stretches, depending on the method used to construct the firebox. Under the influence of high thermal loads, these weak points are destroyed relatively quickly. Water pipes located in the area of the cracks behind the plates are also subject to increased thermal loads.

The proposed technical solution is aimed at increasing the operational reliability and service life of a metal firebox, which is achieved by redirecting deflected hot flows from the corners to the middle part of the wall and more uniformly distributing it along it, as well as increasing the rigidity of the wall and its resistance to thermal deformation.

Disclosure of the invention

The above-mentioned technical problem has been solved and the results have been achieved due to the fact that in a metal furnace firebox containing walls forming a combustion chamber and at least one recovery unit placed in it, including a set of lamellas fixed at their ends in rack-holders with an indentation from the firebox wall and inclined towards it, forming slots between themselves for the passage of flame and flue gases to the wall of the firebox, according to the claimed invention, the lamellas are inclined towards the horizon and grouped between the rack-holders in two mirror-symmetrical rows to form a “herringbone” pattern with the apex directed upward, while the support posts are welded to the inner surface of the firebox wall.

A significant difference of the proposed design is the arrangement of the lamellas in two rows, with an inclination towards the horizon in each row, mirror symmetrically relative to the middle support stand, forming a “herringbone” pattern with the apex directed upward. The gaps formed between such lamellas ensure the creation of thrust directed to the middle of the wall and the removal of hot gases and flames from the corners of the furnace body, which are places of reduced strength. At the same time, rack-holders welded to the inner surface of the furnace wall limit the spread of flames along the surface of the wall and prevent them from entering the corner zones. As a result, the thermal load on the corner zones is reduced, the stability of the firebox corners and their durability are ensured. As tests have shown, the metal temperature in the corner zones of the firebox is significantly lower than in the middle part of the wall.

Due to the fact that two rows of slits are formed, the flame and hot gases are divided into two streams, which contributes to a more uniform distribution of heat (heating) across the width of the wall and improved heat transfer.

The rack-holders welded to the inner surface of the wall form the stiffening ribs of the wall, contributing to its resistance to deformation and warping, and therefore the durability and reliability of operation of the furnace.

In a preferred embodiment of the device, each lamella in the rows is slightly curved in an arc and oriented with the convexity of the bend towards the top of the firebox. The arcuate bend contributes to the formation of a wider passage hole in the middle part of the lamella, and it is here, to the place of least resistance, that the flows of flame and hot flue gases rush. As a result, the thermal load on the ends of the lamellas and the places where they are secured to the rack-holders is reduced, i.e. the thermal load on welding seams is reduced.

At the same time, the arcuate bending of the lamellas creates conditions for their some mobility in the middle part, which makes it possible to compensate for linear thermal expansion and prevent the destruction of joints. All this also helps to increase the reliability and durability of the structure.

Preferably, the lamellas are made with a thickness no less than the thickness of the firebox wall. Increasing the thickness of the lamellas creates additional mass and increases the thermal capacity of the structure.

Unlike the prototype, the water circuit of the steam generator covers the walls of the firebox from the outside. Instead of steam generator pipes, there may be a water heater jacket.

Recovery units can be placed on each wall of the furnace or on some of them.

The middle support post is preferably located in the center of the wall, at an equal distance from the corners.

An insert can be installed in the upper part of the firebox, forming cavities to accommodate the heat-storing load.

Brief description of the drawings The essence of the proposed technical solution is illustrated by examples of specific implementations and drawings, which show: FIG. 1 is a general view of a sauna stove with a firebox, according to the invention; in fig. 2 - section A-A from Fig. 1, only the cross section of the firebox is shown; in fig. 3 - example of a recovery unit, axonometry; in fig. 4 - view A from Fig. 2, view of the furnace wall with the recovery unit attached to it; in fig. 5 - section B-B from Fig. 4.

Carrying out the invention The device of a sauna stove using solid fuel, for example wood, includes (see Fig. 1) a metal firebox 1 with a grate 2, an ash box 3 (ash pan), a door 4 with heat-resistant ceramic glass located in the front wall of the firebox, a water steam generator circuit 5, covering the furnace from the outside (closed with a protective casing), insert 6, forming cavities to accommodate the heat-storing load 7 and performing the function of a flame cutter at the inlet of the chimney 8, usually located in the center of the furnace.

The firebox 1 has a polygonal cross-section, usually in the shape of a rectangle or trapezoid, see FIG. 2.

In the given example, the rear wall 9 and the side walls 10 and 11 of the firebox are formed by bending from a metal sheet, and the front wall 12 is welded to them with welds 13.

The walls 9-12 of the firebox form a combustion chamber 14, in which at least one recovery unit 15 is located (see Fig. 3), including lamellas 16 and 17 arranged in two rows, fixed at their ends in rack-holders 18 with an inclination to the horizon under angle, preferably 30-45°, forming a herringbone pattern. The thickness of the lamellas is preferably equal to or greater than the thickness of the firebox wall material. The lamellas 16 and 17 are slightly curved along the arc 19 and are oriented with their convex upwards.

The supporting posts 18 are thickened plates (bars), welded with one narrow longitudinal edge to the inner surface of the corresponding firebox wall (see Figs. 4 and 5). Their wide longitudinal edges serve to secure the lamellas. The middle support stand is located at an equal distance from the corners of the firebox. The number of block elements is selected based on the conditions of a specific firebox.

In fig. 5 it can be seen that the lamellas 16 (similar to 17) are located indented (with a gap) from the corresponding wall of the firebox, inclined towards it and form slot holes (slots) 20 between themselves, allowing the passage of flame and flue gases (shown by arrows) to the wall fireboxes

Such recovery units 15 can be attached to each wall of the furnace. In the example given, they are located on the front wall 12 above the door 4 through which fuel is loaded, and on the side walls 10 and 11 of the firebox.

During the combustion of fuel, flows of flame and hot gases are captured by inclined lamellas 16 and 17, deviate from the direct path into the chimney and are directed to the corresponding walls of the firebox through slotted holes 20, concentrating the hot flows in the middle part of the wall. Further propagation of hot flows along the walls is limited by the outer support posts 18, which prevents them from entering the corner zones, which are places of weakened strength, most sensitive to high thermal loads.

The arc-curved shape of the lamellas 16 and 17 contributes to the additional direction of hot gases and flames to the center of the lamellas in each of the separated flows, which reduces the thermal load on the places where the ends of the lamellas are secured in the rack-holders, which contributes to the safety of welding seams.

The supporting racks 18 of blocks 15, welded to the internal surfaces of the corresponding walls, help increase their rigidity and resistance to warping (shape distortion), and improve heat transfer conditions.

The mass of lamellas, added to the mass of the firebox, helps to increase the overall heat capacity and increase the efficiency of the stove.

Due to the fact that the lamellas provide a certain direction of the flame, when opening the door 4, flames are prevented from escaping through it, which helps to increase the safety of work when the door is open. In this case, the direction of the flame makes it possible to reduce the contamination of the door glass 4 with soot.

To further increase the thermal power of the furnace, furnace 1 can be equipped with swirl plates mounted above the recovery unit in the upper part of the wall (not shown in the drawings). The swirl helps slow down the flow of exhaust gases in the upper part of the furnace in the area where the heat-storing load 7 is located, which allows for additional heat extraction before removing the gases through the chimney 8.

Claims (7)

1. A metal furnace firebox containing walls forming a combustion chamber and at least one recovery unit placed in it, including a set of lamellas fixed at their ends in rack-holders, indented from the firebox wall and inclined towards it, forming slots between themselves for passage of flame and flue gases to the wall of the firebox, characterized in that the lamellas are inclined to the horizon and are grouped between the rack-holders in two mirror-symmetrical rows to form a herringbone pattern with the apex directed upward, while the rack-holders are welded to the inner surface of the wall fireboxes 2. A metal firebox according to claim 1, characterized in that each lamella is bent in an arc and oriented with the convexity of the bend towards the top of the firebox. 3. Metal firebox according to claim 1, characterized in that the lamellas are made with a thickness no less than the thickness of the firebox wall. 4. Metal firebox according to claim 1, characterized in that the firebox is surrounded from the outside by a water circuit of the steam generator. 5. Metal firebox according to claim 1, characterized in that recovery units are placed on each wall of the firebox. 6. Metal firebox according to claim 1, characterized in that the middle support stand is located at an equal distance from the corners of the firebox. 7. A metal firebox according to claim 1, characterized in that an insert is placed in the upper part of the firebox, forming cavities for placing a heat-accumulating load.