RU142651U1 - HEATING FURNACE - Google Patents

Abstract

1. A heating furnace comprising a vertical furnace casing, mounted on a vertically mounted furnace casing with a combustion chamber configured therein, air supply means, a fuel supply means, a doorway made in the furnace casing in the vicinity of the combustion chamber, a bottom and a furnace lid, the casing the furnace is made in the form of a vertical shell with openings made in it for outlets of hot air, holes are made in the furnace lid for the exhaust gas outlet pipe, an opening for supplying air is made in the bottom of the furnace, while the casing is not chi is mounted on the furnace body with an offset relative to the vertical axis of the furnace and with a gap necessary for the passage of air, and air supply openings are made in the furnace body in the area of the fuel combustion chamber on at least one side of the doorway, while the furnace body has a combustion chamber an inclined evaporation pad is installed, so that the upper edge of the inclined evaporation pad is located on the side of the doorway, and an opening for the fuel supply means is made in the furnace body on the side of the doorway, it is in the form of a fuel supply tube installed directly on the upper edge of the inclined evaporation platform, and the air supply means is made in the form of a fan mounted directly under the bottom of the furnace. 2. The furnace according to claim 1, characterized in that the air supply openings to the combustion chamber are made to the left and right of the doorway, while to the left of the doorway, some of the holes are made vertically in a row, the other part is made in a row with an inclination to the vertical, and the holes on the right from the doorway are made in a row with an oblique

Description

The technical field to which the utility model relates.

The utility model relates to the field of heating, namely to the design of devices designed for heating domestic, technical and industrial premises, for example, garages, service stations, factory floors, etc. The specified heating furnace operates on liquid hydrocarbons such as diesel fuel, waste oil of various internal combustion engines and gear oil, vegetable oil, etc.

State of the art

There are many technical solutions used for space heating.

A heating furnace is known from the prior art (see RU 12721 U1, F24C 13/00, publ. 01/27/2000), comprising a heat exchanger, a housing, inside which there is a combustion chamber with a grate and an ash pan located under it, moreover, the furnace is dismountable, the housing is made of brick, while the bricks are reinforced with a frame, drilled, strung on rods, the lower ends of which are attached to the bottom of the frame, and the furnace is equipped with a burner located on the side wall of the combustion chamber, the heat exchanger is mounted on the housing, the clamp is fixed the frame of the frame to the body, and the radiation part faces the combustion chamber, while the shape of the heat exchanger is made in the form of a prism, for example, an octagonal. The disadvantages of this technical solution is the inability to use liquid hydrocarbons as fuel, as well as the low efficiency of the furnace.

Also known from the prior art is a multi-fuel heating furnace (see RU 2475678 C1, F24C 1/00, publ. 02.20.2013), containing an axisymmetric body forming a combustion chamber, the design of which provides for the creation of natural draft, a movable piston located in the combustion chamber, means of fuel supply, and the movable control piston divides the combustion chamber into a supra-piston and sub-piston volume and is driven by external influence, an axisymmetric atomizer is located inside the combustion chamber, in the construction of the combustion chamber The standard locations for the supply / laying of gaseous, liquid and solid fuels are provided. The disadvantages of this technical solution is the design complexity, low fuel combustion rate, as well as high fire hazard.

Another analogue of the claimed utility model is a continuous heat recovery furnace (see RU 2285205 C2, F24C 5/00, published October 10, 2006), comprising a housing in the lower part of which there is a fuel storage unit with a fuel supply fitting and a metering flap and a chimney in the upper part of the casing, and inside the casing there is a partition forming a firebox, a afterburner, a draft stabilization chamber and a gas passage between the baffle and the fuel storage, the firebox equipped with a door, the metering flap equipped with a blade made with the possibility of swirling the flow of air and flame during combustion and with the possibility of pressing it against the baffle to stop the combustion process, a bore is made in the baffle - a nozzle located under the chimney, providing traction, and two rows of holes for supplying secondary air to the afterburner. The disadvantages of this technical solution is the low efficiency of fuel combustion and high fire hazard.

The closest analogue of the claimed utility model is a self-contained oil-fired heating furnace (see RU 125680 U1, A24C 5/00, published March 10, 2013), comprising a housing with a viewing hole, combined with a combustion chamber with radially offset rows of holes, a heat exchanger, made in one piece with the flue gas pipe, while the upper fuel pipe is installed on the casing, an air pre-heating chamber is installed under the combustion chamber, in which the overflow outlet is located in the lower part, the air I have a shutter with a lock in the side and a removable burner with a double bottom, radially mixed slots, vertical protrusions in the upper part and a holder, the burner connected to the combustion chamber and fixed with a holder fixed to the inner wall of the air preheating chamber, while the heat exchanger and the flue gas pipe is removable, and the combustion chamber is provided with a casing with centering petals. The disadvantages of this technical solution is the poor fuel combustion efficiency, design complexity, low furnace efficiency and high fire hazard.

Utility Model Essence

The problem solved by the claimed utility model is to increase the efficiency of the furnace, increase fire safety and reliability of the heating furnace, as well as ensure fire safety and manufacturability, and increase the area of the heated room.

The technical result of the proposed utility model is to intensify the combustion and heat transfer processes, increase the efficiency of fuel combustion.

The specified technical result is achieved due to the fact that the heating furnace containing a vertical furnace casing, mounted on a vertically mounted furnace body, with a combustion chamber made therein, air supply means, fuel supply means, a doorway made in the furnace body in the vicinity of the combustion chamber , the bottom and the lid of the furnace, and the casing of the furnace is made in the form of a vertical shell, with openings made therein for outlets of hot air, in the lid of the furnace holes are made for the exhaust pipe, not the furnace has a hole for air supply, while the furnace casing is mounted on the furnace body with an offset relative to the vertical axis of the furnace with a gap necessary for air passage, and holes are made in the furnace body in the region of the fuel combustion chamber from at least one side of the doorway air supply, while an inclined evaporation platform is installed in the combustion chamber of the furnace body, so that the upper edge of the inclined evaporation platform is located on the side of the doorway, and in the furnace body on the side of the door oema a hole under the fuel supply means, arranged in a fuel feed tube mounted directly on the upper edge of the inclined evaporator pad, and air supply means is a fan fixed directly below the furnace bottom.

According to the embodiment of the claimed utility model, the openings of the air supply to the combustion chamber are made to the left and right of the doorway, while to the left of the doorway, part of the holes are made vertically in a row, the other part is made in a row with an inclination from the vertical, and the holes located to the right of the door openings, made in a row with a slope from the vertical.

According to the embodiment of the claimed utility model, a heat exchanger is additionally installed in the furnace body, in its upper part, made in the form of a steel hollow cylinder with hermetically sealed upper and lower bases.

According to an embodiment of the claimed utility model, the heat exchanger is removable.

According to an embodiment of the claimed utility model, the heat exchanger contains heat supply and exhaust pipes installed in the upper base of the cylindrical heat exchanger, while the heat transfer pipe to the heat exchanger is longer than the heat transfer pipe and extended along the inner cavity of the heat exchanger to the lower base of the cylindrical heat exchanger, providing a gap between the lower base and the heat transfer tube, while the heat transfer pipe from the heat exchanger is flush with the inside The top surface of the heat exchanger.

According to the embodiment of the claimed utility model, the furnace lid is made of small and large parts, while in the small part of the furnace lid there are openings for pipes for supplying the heat carrier to the heat exchanger and for removing the heat carrier from the heat exchanger, as well as for the exhaust gas pipe.

According to an embodiment of the claimed utility model, the heat exchanger further comprises steel corners vertically mounted on the outer surface of the heat exchanger.

According to the embodiment of the claimed utility model, the heat exchanger further comprises three through vertical channels made from its lower base to the upper base of the heat exchanger.

According to an embodiment of the claimed utility model, the fan is installed to the bottom of the furnace body by means of a spring suspension.

According to the embodiment of the claimed utility model, the inclined evaporation pad is made with a recess.

According to an embodiment of the claimed utility model, the inclined evaporation pad is made expanding from its upper edge to the lower edge.

According to an embodiment of the claimed utility model, horizontal plates are additionally installed over the air supply openings to the combustion chamber on the furnace body.

Brief Description of the Drawings

Details, features, and advantages of this utility model follow from the following description of examples of implementation of the claimed heating furnace using the drawings (Fig. 1-7).

In FIG. 1 is a general view of a heating furnace.

In FIG. 2 - sectional view of a heating furnace with a heat exchanger installed.

In FIG. 3 - design of a heat exchanger of a heating furnace in three versions.

In FIG. 4 - a design of a heat exchanger of a heating furnace in three versions, in section.

In FIG. 5 - housing of the heating furnace.

In FIG. 6 - bottom and cover of the furnace (composite and integral).

In FIG. 7 is an exemplary embodiment of an inclined evaporation pad.

In the figures, the numbers indicate the following positions: 1 - furnace body; 2 - furnace casing; 3 - furnace cover; 4 - openings for the exit of warm air; 5 - pipe exhaust gas; 6 - a pipe for supplying a heat carrier to a heat exchanger; 7 - a pipe of removal of the heat carrier from the heat exchanger; 8 - heat exchanger; 9 - inclined evaporation pad; 10 - air supply openings to the combustion chamber; 11 - fan; 12 - a tube for supplying liquid fuel; 13 - vertical channels of the heat exchanger; 14 - corners of the heat exchanger; 15 - doorway; 16 - most of the composite cover of the furnace; 17 - a small part of the composite cover of the furnace; 18 - bottom of the furnace; 19 - cut in the bottom of the furnace; 20 - legs of the furnace; 21 - horizontal plates.

Utility Model Disclosure

The heating furnace consists of a body (1) of a furnace, a casing (2) of a furnace installed on a body (1) of a furnace, a fuel combustion chamber located in the lower part of the body (1) of the furnace, bottom (18) of the furnace, cover (3) of the furnace, air supply fan (11), liquid fuel supply pipe (12). Also, the specified heating furnace is made with the possibility of additional installation of the heat exchanger (8) in the upper part of the body (1) of the furnace for connecting the claimed furnace to a closed heating system.

The furnace body (1) is made in the form of a hollow cylinder, the lower part of which is a fuel combustion chamber. In the area of the combustion chamber, a doorway (15) is made in the furnace body, into which the furnace door is installed. In the combustion chamber of the fuel at the bottom of the furnace (18) there is an inclined evaporation pad (9) installed in the combustion chamber at the bottom (18) of the legs.

The inclined evaporation pad (9) is made of a thin heat-resistant sheet of metal. The inclined evaporation pad is made expanding from its upper edge to its lower edge, while the inclined evaporation pad (9) is made with a recess, and is set so that the upper edge of the evaporation pad is located on the side of the furnace door.

In the housing (1) of the furnace, an opening is made under the doorway (15) for installing a tube (12) for supplying liquid fuel. The liquid fuel supply pipe is made of copper. The specified liquid fuel supply pipe is mounted directly on the upper edge of the inclined evaporation platform (9).

In the housing (1) of the furnace, in the area of the fuel combustion chamber, openings (10) for supplying air to the combustion chamber are made, which are necessary for high-quality mixing of fuel vapors with incoming air, and, therefore, for efficient combustion of fuel, as well as for the formation of a flame in contact with the body (1) of the furnace, which prevents intensive wear of the body (1) of the furnace.

The holes (10) for supplying air to the combustion chamber are made, for example, to the left and right of the doorway (15), while to the left of the doorway some of the holes (10) are made vertically in a row, the other part of the holes (10) are made in a row with a slope from the vertical, and the holes (10) made to the right of the doorway (15) of the furnace are arranged in a row with an inclination from the vertical. The openings (10) for supplying air to the combustion chamber are made in the housing (1) of the furnace above the inclined evaporation platform (9). The specified hole (10) in the housing (1) of the heating furnace contribute to the creation of an additional vortex air flow, which contributes to an additional tightening of the flame and complete combustion of the fuel.

For more efficient air supply to the combustion chamber on the outer surface of the furnace body (1) above the holes (10) of the air supply to the fuel combustion chamber, horizontal plates (21) are additionally installed, which reduce the air flow rate created by the fan (11) in the space between the casing ( 2) and the body (1) of the furnace, thereby directing an additional volume of air into the fuel combustion chamber through the openings (10) for supplying air.

The casing (2) of the furnace is a vertical jacket connected to the cover (3) of the furnace and the bottom (18) of the furnace. The bottom (18) and the cover (3) of the furnace are also connected to the body (1) of the furnace.

In the jacket of the casing (2) of the furnace, holes (4) are made for the outlet of hot air from the furnace to heat the room. On the casing (2) of the furnace to the indicated openings (4) for the outlet of hot air, it is possible to additionally install standard flanges for attaching corrugated hoses and supply heat to them in at least two rooms; Thus, it is possible to heat the room in which the proposed furnace is installed, and at least one neighboring room.

Also in the casing (2) of the furnace, an opening is made under the door of the furnace, while the casing (2) of the furnace is fixed to the body (1) of the furnace in the vicinity of the doorway (15) by means of a transition frame (not shown in Fig.).

The cover (3) of the furnace is a metal disk with a diameter equal to the diameter of the casing (2) of the furnace.

The furnace lid (3), depending on the variants of the claimed utility model, can be made as one-piece, in the case of using a furnace without a heat exchanger (8), and as a composite of two, inserted into one another large (16) and small (17) parts , in case of additional installation of the heat exchanger (8).

In an embodiment of the proposed heating furnace without a heat exchanger (8), the cover (3) of the furnace is made in the form of a solid disk, with an opening for the exhaust gas outlet pipe (5).

In an embodiment of the proposed heating furnace with a heat exchanger (8), the cover (3) of the furnace is made integral, while in the small (17) part of the composite cover (3) of the furnace, holes are made for the supply pipes (6) of the heat carrier to the heat exchanger and the heat carrier (7) from the heat exchanger (8).

The bottom (18) of the furnace is a disk with a sickle-shaped cutout (19) made in it, offset from the central axis of the furnace. The bottom (3) of the furnace is set so that the offset sickle-shaped cut-out (19) is located closer to the rear wall of the furnace (on the opposite side of the doorway), for air to pass from the fan (11) into the space formed between the casing (2) and the body ( 1) furnaces.

The fan (11) is tightly installed to the bottom (3) of the furnace. The fan (11) is fastened and snug against the bottom (3) of the furnace by means of a spring suspension (not shown in Fig.). For ease of maintenance and repair of the fan (11) without dismantling the furnace, it is made removable.

The fan (11) is a channel (centrifugal) with a capacity of 1000 m per hour. The fan (11) is designed to pump air into the space between the casing (2) of the furnace and its body (1). Due to the excess air pressure created by the fan (11) in the space between the casing (2) and the furnace body (1), part of the air enters the fuel combustion chamber through openings (10) made in the housing (1) to ensure high-quality fuel combustion furnace in the area of the fuel combustion chamber, the rest of the air passes between the casing (2) of the furnace and the housing (1), providing heating of the air.

In addition, the fan (11), located directly below the combustion chamber, intensively cools the bottom (3) of the furnace, as a result of which a limitation of the volume of combustible fuel that has uncontrolledly entered the combustion chamber, i.e. only that fuel burns that enters the inclined evaporation pad (9), raised from the bottom of the furnace. If the amount of incoming fuel exceeds the maximum possible amount ensuring its normal combustion (which is an emergency), then excess fuel flows down the inclined evaporation platform (9) to the cooled bottom (3) of the furnace, where combustion does not occur. At the same time, surplus fuel accumulates at the bottom (3) of the furnace and the inclined evaporation platform (9) is gradually immersed in the accumulated volume of non-burning fuel, fuel combustion stops and the furnace stops working. Thus, the fire safety of the specified heating furnace, made according to the claimed utility model, is additionally ensured.

The heating furnace, according to the claimed utility model, is made with the possibility of additional installation of a removable heat exchanger (8).

An additional installation of the heat exchanger (8) allows you to connect the claimed heating furnace to a closed heating system, including pipelines and heating radiators, which in turn allows for heating of an additional volume of the room area.

The heat exchanger (8) is located in the upper part of the furnace body (1) and is made in the form of a steel hollow cylinder with hermetically sealed upper and lower bases, while holes in the upper base are made for installing the supply pipes (6) and the coolant outlet (7) in them .

The tube (6) for supplying the heat carrier to the heat exchanger is made longer than the tube (7) for removing the heat carrier and passes through the internal cavity of the heat exchanger (8) to the lower base of the cylindrical heat exchanger. In this case, the supply pipe (6) of the coolant to the heat exchanger (8) is installed at a distance from the lower base to ensure normal supply of the coolant to the heat exchanger (8).

The pipe (7) for removing the heat carrier from the heat exchanger (8) is installed flush with the inner surface of the upper base of the heat exchanger.

In one embodiment of the claimed utility model, in order to provide more efficient heat removal from exhaust gases and additional heat transfer to the heat exchanger body (8), the side surface of the cylindrical heat exchanger (8) is additionally equipped with vertically mounted steel corners (14). The corners (14) are mounted on the side surface of the heat exchanger (8) with the apex to the heat exchanger and are welded to the surface of the heat exchanger (8) with a continuous seam on both sides of the corner apex (14).

In another embodiment of the claimed utility model, from the lower base of the heat exchanger (8) to its upper base, three through vertical channels (13) are formed, formed by installing three tubes in the cavity of the heat exchanger, which ensures the passage of the ascending hot gases through the said channels, which is achieved additional heat transfer.

A thread is made on the supply pipes (6) and the outlet (7) of the heat carrier to the heat exchanger (8), by which the heat exchanger (8) is fixed to the composite cover (3) of the furnace, and also by the specified thread of the tube (6) and (7) be connected to a closed heating system.

The claimed heating furnace operates as follows: Liquid fuel supplied to a pre-heated inclined evaporation pad located inside the chamber spreads in a thin layer over the entire width of the inclined evaporation pad without forming a significant amount of liquid fuel. Thus, uncontrolled burning of significant volumes of liquid fuel is prevented and the fire safety of the claimed heating furnace is increased.

The resulting carbon is wetted by newly incoming liquid fuel and burns, thus increasing the interval between maintenance of the claimed furnace. The flame swirls around the axis of the vortex air flow formed by making holes in the body of the heating furnace. Power adjustment is carried out by adjusting the supply of liquid fuel.

The fan located at the bottom of the furnace pumps air into the space between the housing and the casing, and also pumps air into the fuel combustion chamber by blowing the furnace body and heat exchanger (in one embodiment), the air is heated and forced to enter the room, and the exhaust gases enter chimney and are removed from the premises to the street. If there is a heat exchanger in the furnace, the exhaust gases wash the heat exchanger, heating the heat carrier contained in it.

Fuel is supplied either by gravity from a tank installed above the level of the combustion chamber, or by means of an electromechanical fuel pump with adjustable fuel supply.

On the fuel supply pipe, directly next to the fuel tank, a tap is installed to shut off the fuel supply. Also on the fuel supply pipe, between the valve and the tank, it is possible to install a normally-closed solenoid valve, which closes when the power supply is disconnected (in the event of an emergency power outage), stopping the fuel supply to the combustion chamber. The specified design can further improve the safety of the furnace. In the event of an emergency power outage, a fan powered from the mains stops working, which can lead to uncontrolled burning of large volumes of fuel, incomplete combustion, as a result of which overfilling is possible.

Claims (12)

1. A heating furnace comprising a vertical furnace casing, mounted on a vertically mounted furnace casing with a combustion chamber configured therein, air supply means, a fuel supply means, a doorway made in the furnace casing in the vicinity of the combustion chamber, a bottom and a furnace lid, the casing the furnace is made in the form of a vertical shell with openings made in it for outlets of hot air, holes are made in the furnace lid for the exhaust gas outlet pipe, an opening for supplying air is made in the bottom of the furnace, while the casing is not chi is mounted on the furnace body with an offset relative to the vertical axis of the furnace and with a gap necessary for the passage of air, and air supply openings are made in the furnace body in the area of the fuel combustion chamber on at least one side of the doorway, while the furnace body has a combustion chamber an inclined evaporation pad is installed, so that the upper edge of the inclined evaporation pad is located on the side of the doorway, and an opening for the fuel supply means is made in the furnace body on the side of the doorway, It is in the form of a fuel supply tube installed directly on the upper edge of the inclined evaporation platform, and the air supply means is made in the form of a fan mounted directly under the bottom of the furnace. 2. The furnace according to claim 1, characterized in that the air supply openings to the combustion chamber are made left and right with respect to the doorway, while to the left of the doorway some of the holes are made vertically in a row, the other part is made in a row with an inclination to the vertical, and holes to the right of the doorway are made in a row with an inclination to the vertical. 3. The furnace according to claim 1, characterized in that in the furnace body, in its upper part, an additional heat exchanger is installed, made in the form steel hollow cylinder with hermetically sealed upper and lower bases. 4. The furnace according to claim 3, characterized in that the heat exchanger is removable. 3. The furnace according to claim 3, characterized in that the heat exchanger contains tubes for supplying and discharging the heat carrier installed in the upper base of the cylindrical heat exchanger, while the tube for supplying the heat carrier in the heat exchanger is longer than the tube for discharging the heat carrier and extended along the inner cavity of the heat exchanger to the lower base a cylindrical heat exchanger, providing a gap between the lower base and the heat transfer tube, while the heat transfer pipe from the heat exchanger is flush with the inner surface Tew upper base of the heat exchanger. 5. The furnace according to claim 1 or 3, characterized in that the furnace lid is made of composite small and large parts, while in the small part of the composite lid of the furnace holes are made for pipes for supplying the heat carrier to the heat exchanger and for removing the heat carrier from the heat exchanger, as well as for the pipe exhaust gases. 6. The furnace according to claim 3, characterized in that the heat exchanger further comprises steel corners vertically mounted on the outer surface of the heat exchanger. 7. The furnace according to claim 3, characterized in that the heat exchanger further comprises three through vertical channels made from its lower base to the upper. 8. The furnace according to claim 1, characterized in that the fan is installed to the bottom of the furnace body by means of an elastic suspension. 9. The furnace according to claim 1, characterized in that the inclined evaporation platform is made with a recess. 10. The furnace according to claim 1, characterized in that the inclined evaporation platform is made expanding from its upper edge to the lower edge. 11. The furnace according to claim 1, characterized in that horizontal plates are additionally installed above the air supply openings in the combustion chamber on the furnace body.

Images