RU110820U1 - CHIMNEY FOR DISCHARGE OF COMBUSTION PRODUCTS - Google Patents

Abstract

 1. The chimney for the removal of combustion products of mainly domestic stoves, characterized in that the chimney contains a chimney, preferably in the form of a hollow thin-walled cylinder, consisting of at least two interconnected sections, preferably three or more, mainly having devices for blocking it the cross-section and for the entry / exit of combustion products, while at least one section of the chimney, preferably connecting the combustion zone to the chimney, is made to rotate it wok a circle of the longitudinal axis of the chimney and subsequent fixation in the selected position, the axes of the inlet and outlet parts of this section being made intersecting, preferably lying in the same plane with the axis of the chimney. ! 2. The chimney according to claim 1, characterized in that the inlet of the chimney is made at an angle of 90-180 °, mainly at an angle of 135 °, to the vertical axis of the furnace. ! 3. The chimney according to claim 1, characterized in that the axes of the input and output parts of the indicated section are made intersecting at an angle of 90-180 °, mainly at an angle of 135 °. ! 4. The chimney according to claim 1, characterized in that the input and output parts of the indicated section are interconnected along a curve, preferably along a circular arc. ! 5. The chimney according to any one of claims 1 and 4, characterized in that the input and output parts of the indicated section are interconnected along an arc of a circle, and the mating radius R is selected from the relation R = (40 ... 65) S, where R is the mating radius parts of the section among themselves; S is the wall thickness of the section. ! 6. The chimney according to claim 1, characterized in that the length of the rectilinear output part of the indicated section from the point of its conjugation with the input part is selected before

Description

The utility model relates to heating furnaces and can be used in the design of furnaces and heating devices for cooking and heating a room.

Known solid fuel furnace containing a combustion chamber with a visor in its upper part, which is adjacent to the side and rear walls and divides the combustion chamber into upper and lower parts, a door with a glazed window on the front wall of the combustion chamber for loading fuel, lower and slit upper air supply for blowing the glass of the door window with a flat air stream and forming inside the combustion chamber a region of afterburning of the combustion products of fuel and a pipe for the removal of combustion products located in the upper rear part amers of combustion.

The air for primary combustion of solid fuel is supplied to the combustion chamber both from the side of the rear wall of the furnace and from the side of the lower part of the front wall of the combustion chamber using dampers controlled from the front of the furnace. The afterburning of unburned fuel particles is carried out by supplying two air streams to the combustion chamber, one of which is cold, controlled by a damper, and the second, uncontrollable warm, after blowing the glass of the door, it enters the front of the combustion chamber into the afterburning area of unburned solid fuel products. The walls of the combustion chamber are lined with brickwork and placed inside a metal casing. Between the walls of the combustion chamber and the casing there is a space through which air is drawn from the lower part of the heated room to cool the furnace casing (patent US 4766876 A, F24B 5/02, 08/30/1988).

The disadvantage of this method of exhausting combustion products is that when the composition of the solid fuel is changed, a sufficiently high efficiency (efficiency) of the furnace is not provided. In addition, the rigid sealing of the elements of the chimney does not allow optimal placement of the furnace in designated premises. Another significant drawback is the brick lining of the furnace walls, which reduces its mobility for heating summer and temporary buildings.

A heating device is known comprising a housing formed by an upper plane, side, front and rear walls, the upper part of the housing with a front wall being made protruding forward above the furnace door; chimney hatch located in the upper part of the body; grate installed in the bottom of the housing; a blower located under the grate and communicating with the internal cavity of the body through its openings; straight ducts made in the form of pipes with open ends communicating with atmospheric air, installed along the rear and protruding parts of the front walls inside the housing, and the ends of the direct ducts located at the rear wall are rigidly fixed in the holes of the bottom and upper parts of the housing, and the ends of the straight air ducts located near the front wall are rigidly fixed in the holes of the upper plane of the housing and the bottom of the protruding upper part of the housing; curved air ducts with open ends communicating with atmospheric air are staggered along the side walls of the housing, while the ends of their straight parts are rigidly fixed in the holes of the bottom of the body, and the opposite ends of the curved part are rigidly fixed in the holes of the opposite upper parts of the side walls of the body, and the intersecting upper parts form a combustion chamber, consisting of two zones: the lower - the furnace, equipped with a door on the front wall of the casing, and the upper zone of the combustion chamber; nozzles with open ends for supplying air to the upper zone of the combustion chamber, bent towards the air flow and rigidly fixed in straight ducts so that one end enters the direct ducts located opposite each other, and the second is located in the upper part of the combustion chamber, in addition, it equipped with upper and lower screens forming gas ducts, and the upper screens are located on the inclined parts of the curved ducts on the outside of the combustion chamber arch, while the upper screens are installed with a gap relative to each other along their entire length, and the lower screens are located on the inclined parts of the curved ducts on the inner side of the combustion chamber roof, with the chimney hatch and the upper end of at least one of the straight ducts located in the upper part of the rear wall of the casing, and the end face of the tubular the element located in the cavity of the pipe of the device for collecting condensate is located at an angle to its central axis (RF patent for utility model No. 82821, IPC: P24B 5/06, P24B 7/02 - prototype).

The heating device operates as follows.

Previously, the ash pan is slightly pushed out of the blower, and if the door is used, it is slightly opened to allow air from outside to the furnace through the grate to create traction. Through the door of the furnace, solid fuel is loaded into the furnace and set on fire. Fuel burns on the grate. The intensity of combustion is regulated by the extension of the ash pan. After the main fuel has ignited, the operation of the device is transferred to the economical mode, for which the ash pan is pushed into the blower. The part of the fuel that is not burnt in the furnace in the form of flue gas components rises to the upper zone of the combustion chamber, where it is burned, which is facilitated by heated air, which additionally enters through pipes from direct air ducts. When the ends of the nozzles are located in the upper zone of the combustion chamber, at different levels, the uniformity of its distribution over the volume of the combustion chamber increases, which increases the completeness of combustion, and therefore provides higher heat transfer. The presence at the ends of the nozzles of air flow control devices, for example, jets, allows for the adjustment of the air supply to the upper part of the combustion chamber. In the process of fuel combustion, intense heating of straight and curved ducts located in the combustion chamber occurs. The heated air from the air ducts tends to move upward, due to convective forces it flows through the upper ends to the heated room, and the colder air, under the influence of the vacuum formed in the air ducts, is drawn into their lower ends, thus, intensive air circulation through the air ducts occurs, quickly heating up the whole room. When there is a lack of air in the furnace, when the blower is closed, slow smoldering occurs, releasing hot flue gases, which, rising into the upper zone of the combustion chamber, become denser, directed further by the surfaces of the lower and upper gas guide screens to the chimney hatch. Combustible gases are oxidized along the way under the influence of atmospheric air entering the pipes with the release of heat.

The main disadvantage of this heating device is that the rigid sealing of the elements of the chimney does not allow optimal placement of the furnace in designated premises.

The objective of the utility model is to eliminate these drawbacks and create a chimney design for the removal of combustion products, the use of which will simplify the design of the furnace, improve its mass-dimensional characteristics and the conditions of service and operation of the furnace.

The solution to this problem is achieved by the fact that in the proposed chimney for the removal of combustion products, mainly household stoves, according to the technical solution, the chimney contains a chimney, preferably in the form of a hollow thin-walled cylinder, consisting of at least two sections interconnected, preferably three or more, mainly having devices for blocking its bore and for entering / exiting combustion products, at least one chimney section, preferably connecting well, combustion with a chimney, made with the possibility of its rotation around the longitudinal axis of the chimney and subsequent fixation in the selected position, the axes of the input and output parts of this section are made intersecting, preferably lying in the same plane with the axis of the chimney.

In an embodiment, the inlet of the chimney is made at an angle of 90-180 °, preferably at an angle of 135 °, to the vertical axis of the furnace.

The upper value of the specified ratio is selected based on the fact that with a further increase in it, the chimney tilts in the opposite direction with respect to the furnace body, which leads to a deterioration in the removal of combustion products.

The lower value of the specified ratio is selected based on the fact that with a further decrease in it, the chimney elements tilt downward with respect to the furnace body, which leads to a deterioration in the removal of combustion products.

In an embodiment, the axes of the input and output parts of this section are made intersecting at an angle of 90-180 °, mainly at an angle of 135 °.

The upper value of the specified ratio is selected based on the fact that with its further increase, the chimney tilts in the opposite direction with respect to the furnace body.

The lower value of the specified ratio is selected based on the fact that with a further decrease in it, the chimney elements tilt downward with respect to the furnace body, which leads to a deterioration in the removal of combustion products.

In an embodiment, the input and output parts of the indicated section are conjugated along a curve, preferably along a circular arc.

In an embodiment, the input and output parts of the indicated section are interconnected along an arc of a circle, and the conjugation radius R is selected from the relation R = (40 ... 65) S, where: R is the radius of conjugation of the section parts between each other, S is the thickness of the section wall.

The upper value of the specified ratio is selected based on the fact that with a further increase in it, there is an increase in the coupling radius, and, accordingly, a deterioration in the mass-dimensional characteristics of the chimney.

The lower value of the specified ratio is selected based on the fact that with a further decrease in it, corrugation occurs on the inner surface of the section, which leads to the formation of stress concentrators and burnout of the section at the corrugation sites.

In an embodiment, the length of the rectilinear output part of the indicated section, from the point of its conjugation with the input part, is selected within L = (0.5 ... 10) D, where: L is the length of the rectilinear output part of the section, D-diameter.

The upper value of the specified ratio is selected based on the fact that with its further increase, the mass-dimensional characteristics of the furnace deteriorate.

The lower value of the specified ratio is selected based on the fact that with its further decrease, the conditions of the fit of the moving part of the section to the stationary part of the chimney worsen.

In an embodiment, said section is made of at least two sections, preferably three or more, interconnected, the input and output sections being made straight cylindrical.

The essence of the utility model is illustrated by drawings, in which Fig. 1 shows a movable chimney section, in Fig. 2 - a furnace with exhaust products upward, in Fig. 3 - a furnace with exhaust products backward or side-right / left, in Fig. 4 - a furnace with the removal of combustion products upward in a perspective view, in Fig. 5 - a furnace with removal of combustion products back in a perspective view, in Fig. 6 - a furnace with removal of combustion products side-right / left in a perspective view. In the figures, the angle α is indicated — the angle between the sections.

The proposed chimney can be installed in the furnace of the following design.

The furnace 1 contains a combustion zone 2. In the upper part of the combustion zone 2, a pipe 3 is installed. On the pipe 3 is installed with the possibility of changing its position relative to the furnace body 1 section 4 connected to the chimney 5, including the chimney 6. By changing the position of the section 4 with respect to the furnace body 1, when it is rotated around the axis of rotation by 180/90 °, the direction of movement of the combustion products changes - either up and down into the chimney 6, or back or side-right / left and then up into the chimney 6. Such a constructive execution ix chimney 5 allows the desired outlet direction of the combustion products by changing the position of section 4, without changing the position of the furnace 1 itself.

The proposed device operates as follows.

The combustion products obtained in the combustion zone 2 of the furnace 1 are discharged through a pipe 3 installed in the upper part of the combustion zone 2 of the furnace body 1, and then pass through the section 4, made with the possibility of changing its position relative to the furnace body 2, into the chimney 5, including the chimney 6. By changing the position of the section 4 with respect to the furnace body, when it is rotated around the axis of rotation by 180/90 °, the direction of movement of the combustion products changes — either up and down into the chimney 6, or back or side- right / left and far up to the chimney 6. This constructive arrangement allows the chimney 5 the required discharging direction of the combustion products by changing the position of section 4.

The tests of the full-sized sample of the proposed chimney by the author and applicant confirmed the correctness of the design and technological solutions and the proposed criteria.

Using the proposed technical solution will simplify the design of the furnace, improve its mass-dimensional characteristics and conditions of maintenance and operation of the furnace.

Claims (7)

1. The chimney for the removal of combustion products of mainly domestic stoves, characterized in that the chimney contains a chimney, preferably in the form of a hollow thin-walled cylinder, consisting of at least two interconnected sections, preferably three or more, mainly having devices for blocking it the cross-section and for the entry / exit of combustion products, while at least one section of the chimney, preferably connecting the combustion zone to the chimney, is made to rotate it wok a circle of the longitudinal axis of the chimney and subsequent fixation in the selected position, the axes of the inlet and outlet parts of this section being made intersecting, preferably lying in the same plane with the axis of the chimney. 2. The chimney according to claim 1, characterized in that the inlet of the chimney is made at an angle of 90-180 °, mainly at an angle of 135 °, to the vertical axis of the furnace. 3. The chimney according to claim 1, characterized in that the axes of the input and output parts of the indicated section are made intersecting at an angle of 90-180 °, mainly at an angle of 135 °. 4. The chimney according to claim 1, characterized in that the input and output parts of the indicated section are interconnected along a curve, preferably along a circular arc. 5. The chimney according to any one of claims 1 and 4, characterized in that the input and output parts of the indicated section are interconnected along an arc of a circle, and the mating radius R is selected from the relation R = (40 ... 65) S, where R is the mating radius parts of the section among themselves; S is the wall thickness of the section. 6. The chimney according to claim 1, characterized in that the length of the rectilinear output part of the indicated section from the point of its conjugation with the input part is selected within L = (0.5 ... 10) D, where L is the length of the rectilinear output part of the section; D is the diameter. 7. The chimney according to claim 1, characterized in that the said section is made of at least two sections, preferably three or more, paired with each other, and the inlet and outlet sections are made straight cylindrical.