KR101972837B1 - Fireplace hypocaust heating system with warm wind supply - Google Patents

Abstract

The present invention relates to provide a fireplace hypocaust heating system with warm air supply in which a combustion chamber (16) is provided therein and is installed in a fireplace (22) under a hypocaust. The combustion chamber (16) comprises: a fireplace stove (10) communicating with the fireplace (22); a room with the hypocaust formed on the fireplace (22) by the hypocaust; and a blower (50) for supplying air to an air inlet (10IH) communicated with the combustion chamber (16) of the fireplace stove (10). The blower (50) is provided with an external intake pipe and an internal intake pipe, wherein the external intake pipe is in communication with the outside of the room with the hypocaust and the internal intake pipe is in communication with the inside of the room with the hypocaust.

Description

Fireplace hypocaust heating system with warm wind supply}

The present invention relates to a firewood-fired integrated stove stove, and more particularly, to a hot air combined firewood stove stove system of a new configuration that can be expected a variety of desirable results, such as maximizing energy efficiency and multi-functional utilization of heat generated.

In general, gudeulbang is also called the ondol room, the traditional Korean floor structure. Goodulbang is a structure that warms the room by heating the spheres (slab or ocher) on the floor, the spheres are heated directly by the flame, but the air in the room is heated by the heated spheres. In recent years, there has been a growing number of buildings that form spheres with ocher due to increased interest in health. The room which is formed by laying ocher on the floor can be called goodulbang.

However, there is a problem in that the construction takes a lot of time and the homogeneity of the product is not guaranteed due to the complexity and difficulty of the ship construction during the construction.

In addition, the problems of efficient use and reduction of the construction-related energy of the existing spheres, such as raw materials and costs arise.

In terms of energy management after construction, the existing method has a lot of waste heat that is thrown away by the chimney after heating the primary heating energy.

Korean Patent Publication No. 2001-0097383 (November 8, 2001) Korean Patent Publication No. 10-2017-0011319 (published Feb 02, 2017) Korean Patent Registration No. 10-1667746 (registered October 13, 2016)

It is an object of the present invention to provide a hot air combined firewood stove. Specific objects of the present invention are as follows.

1. Modularity of construction

Produced by hearth, firewood, and chamber

Allows DIY construction of the general public

Maximize energy efficiency

Multi-functional use of generated heat (use of hot air drying box, convection heating indoor)

2. Securing technology for efficient management of energy

The present invention seeks to secure a technique for activating a laminated structure of air to ensure natural convection and heat accelerated thermal rotation of a circular or rectangular chamber through standardized overflow.

The internal structure of the plural diaphragm structure in the firewood stove is a technology for generating and moving heat through the flow of the lattice of the multi-layered laminated structure by suctioning indoor air through the indoor air inlet. It aims to secure the function of covering the indoor air, and to secure the drying function such as laundry drying and fruit drying and the auxiliary function that can control the indoor humidity through these functions.

In addition, through the valve of the separate shielding intelligent to secure the function to enable the transfer of heat to the separate space, such as floor, living room.

According to the present invention for solving the above problems, the combustion chamber is provided in the inside of the bulbs in the bottom of the sphere and the combustion chamber is a firewood stove in communication with the arch; It is provided with a warm air combined with a firewood fireplace stove system characterized in that it comprises ;;

And a blower for supplying air to the air inlet communicated with the combustion chamber of the stove.

The blower is provided with an external intake pipe and an internal intake pipe, wherein the external intake pipe is communicated with the outside of the bulb, and the internal intake pipe is communicated with the interior of the bulb.

The fireplace is an outer stove body; A combustion chamber embedded in the outer hearth spaced apart from each other by a predetermined interval; And a support piece for supporting the combustion chamber in a state spaced apart from the inner surface of the outer hearth body by a predetermined distance, wherein the inner space part spaced between the combustion chamber and the outer hearth body is formed as an adiabatic space part.

A blower is connected to the blower pipe connecting the blower to the air inlet of the fireplace, the inhaler is installed in a room other than the bed room, and the intake is characterized in that the filter is provided.

The firewood stove is installed in the firewood beneath the spheres, the chimney is connected to the firewood, the circumference of the chimney is arranged with a heat circulation pipe, one end of the heat circulation pipe is in communication with the firewood, the heat The other end of the circulation pipe is characterized in that it is configured to communicate with the outside of the building.

The spheres are composed of ocher spheres, the indoor room provided with the ocher spheres are ocher gudulbang, characterized in that the heating pipe is buried in the floor of the other room room other than the ocher guulbang.

The heat pipe is characterized in that the fan is connected.

The spheres are composed of ocher spheres, characterized in that the ocher spheres are embedded with a heating pipe for ocher spheres.

It is characterized in that the fan is connected to the heating pipe for the ocher spheres.

The heating pipe is characterized in that it is embedded in a plurality in parallel on the floor.

The outer stove body is provided with an air inlet and a heat outlet, the first circulation chamber through which the air enters through the air inlet is a first circulation chamber, the circulation chamber partitioned from the first circulation chamber by the first circulation guide partition wall is a second And a first passage hole provided in the first circulation guide partition wall to communicate the first circulation chamber and the second circulation chamber at a position spaced a predetermined distance from the air inlet when the arch is viewed from one side of the stove. The circulation chamber is disposed in the last circulation chamber through which the heat escapes through the thermal outlet 10HP, the Nth circulation chamber, and the circulation guide partition wall partitioning the Nth circulation chamber and the N-1th circulation chamber is an N-1 circulation guide partition wall. The through-holes provided in the N-1 circulation partition wall to communicate the N-1th circulation chamber and the Nth circulation chamber become N-1th passage holes. , N-1 second pass holes is characterized in that disposed at a distance spaced apart position from the discharge port when the heat on the other side a cross-sectional view of the furnace hearth.

The heating pipe is built in the spheres to form a heating pipe for the goose, characterized in that the damper is provided between the heating pipe for the ball and the heating pipe built in the floor of the other indoor room of the building.

A branch pipe is connected between the heating pipe for the goose and the heating pipe built in the floor of another indoor room of the building, and the damper is provided in the branch pipe, and the damper selectively selects the heating pipe for the goose and the thermal pipe. Characterized in that configured to open with.

A fan is connected to each of the heating pipe and the heating pipe for the goose, and the suction of the heat is made into the heating pipe and the heating pipe for the goose to the fan, and configured to supply the heat to the indoor room and the sleeping room. It is characterized by.

A chimney is communicated to the fire arch formed below the spheres of the gourd chamber, a circumferential portion of the chimney is further provided with a heat circulation tube, and one end of the heat circulation tube is configured to communicate with the fire arch below the spheres, the heat The other end of the circulation pipe is characterized in that configured to communicate with the outside air.

The arbor is provided with a mound, and part of the thermal circulation tube is embedded to penetrate the mound, characterized in that the one end of the thermal circulation tube is configured to communicate with the interior of the arch.

The thermal circulation pipe is characterized in that it comprises a coiled thermal circulation pipe portion disposed on the outer peripheral surface of the chimney.

An air inlet guide tube is connected to the coiled thermal circulation tube, and an end of the air inlet guide tube is disposed below the upper end of the chimney, and the other end of the thermal circulation tube is connected to the outside air by the air inlet guide tube. Characterized in that configured to communicate.

The effect of the hot air combined firewood fireplace stove system according to the present invention is as follows.

It has the effect of generalizing the expertise of shipbuilders of existing heating systems.

Construction management costs are reduced.

There is a rapid heating function. Due to the characteristics of the ondol, it takes about 3 to 4 hours to light the fire in the ondol room, but the heating time of the indoor surface is shortened to about 30 minutes due to the increase in the internal temperature through the priority heating supply of air in the application of the present invention. .

It is equipped with a hot air box shutoff valve and applies a multi-functional heat utilization system by applying indoor or outdoor air intake or other indoor space piping.

The hot air box is installed in the inside of the room, and has the advantage that the multifunctional function of drying function, humidity control function and internal temperature management function is provided by receiving heat passing through the multilayer lamination grating in the integrated structure.

With the indoor and outdoor air intake, a natural principle using the natural convection of indoor and outdoor air and the covered air is applied to promote the activation of the indoor air flow and the effect of promoting the air flow to the saddle.

Other indoor space is provided with a piping and a shielding valve, the function located between the room and the warm air box has the effect of the auxiliary function to be available through the control of the shielding valve when you want to heat the living room floor in the room.

1 is a front perspective view of a firewood stove which is a main part of a hot air combined firewood stove for burning stove system according to the present invention;
FIG. 2 is a rear perspective view of the firewood stove shown in FIG. 1; FIG.
FIG. 3 is a photograph showing a state in which the arch of FIG. 1 is installed on a wall of a stove.
Figure 4 is a cross-sectional view showing a state in which the hot air combined use of the arch firewood combined with the main part of the firewood fireplace system according to the present invention installed in the firewood in the firewood
5 is a plan view schematically showing a state in which the heat pipes and the heat pipes for the heat pipes, which are other main parts of the hot-air combined fire-fighting fireplace system according to the present invention, are respectively installed on the indoor room floor of the building and the spheres of the bulbs.
FIG. 6 is a plan view showing a state in which the heated pipe side for the ball shown in FIG. 5 is closed by a damper;
7 is a plan view showing a state in which the heat pipe side shown in FIG. 5 is closed by a damper.
FIG. 8 is a cross-sectional view illustrating a state in which the warming pipe for the balls shown in FIG. 5 is embedded in the balls.
9 is a cross-sectional view showing an embodiment in which the heat circulation pipe is installed at the periphery of the chimney shown in FIG.
10 is a side perspective view schematically illustrating a process in which air flows around a combustion chamber in the inside of a stove, which is a main part of a hot air cumulative bulbus stove, according to the present invention;
11 is another side perspective view schematically showing a process in which air flows around the combustion chamber in the inside of the stove, which is a main part of the hot-air combined use of the fire-fighting fireplace, according to the present invention.
12 is a side cross-sectional view schematically showing a process in which air flows around a combustion chamber in the inside of a stove, which is a main part of a hot air combined firewood stove, according to the present invention.
FIG. 13 is another cross-sectional view schematically illustrating a process in which air flows around a combustion chamber in the inside of a stove, which is a main part of a hot air combined firewood stove, according to the present invention.
14 is a front cross-sectional view showing the internal structure of the subfamily stove, which is a main part of the hot air combined firewood stove, according to another embodiment of the present invention.
FIG. 15 is a side perspective view schematically illustrating a process in which air flows around a combustion chamber in the interior of a stove in the arch of FIG. 14;
FIG. 16 is another side perspective view schematically illustrating a process in which air flows around the combustion chamber in the interior of the stove of the arch in FIG. 14;

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. The objects, features and advantages of the present invention will be more readily understood by reference to the accompanying drawings and the following detailed description. In addition, in describing the present invention, when it is determined that the detailed description of the related well-known configuration or function may obscure the gist of the present invention, the detailed description thereof will be omitted.

In addition, in describing the component of this invention, terms, such as 1st, 2nd, A, B, (a), (b), can be used. These terms are only for distinguishing the components from other components, and the nature, order or order of the components are not limited by the terms. For example, if a component is described as being "connected", "coupled" or "connected" to another component, that component may be directly connected or connected to that other component, but between each component. It is to be understood that another component may be "connected", "coupled" or "connected".

Referring to the drawings, the hot-air combined arch firewood stove system according to the present invention is a firewood stove (10) installed on the firewood (22) in the lower part of the spheres, a ballet room formed on the firewood (22) by the spheres, and the firewood stove ( The blower 50 which supplies air to the air inlet 10IH communicated with the combustion chamber 16 of 10) is included as a basic structure.

The fireplace 10 is provided with a combustion chamber 16 inside the outer stove body (12). The outer stove body 12 is box shaped. In the present invention, the outer stove body 12 is a rectangular box shape.

A plurality of partition walls 14 are provided on the inner surface of the outer hearth body 12. The proximal end of each partition 14 is connected to the inner surface of the outer stove body 12. A plurality of partitions 14 are disposed in the radial direction with respect to the center of the outer hearth body 12. The front plate 12FP of the outer stove body 12 is provided with a combustion chamber coupling hole. The front end of the combustion chamber 16 is connected to the combustion chamber coupling hole. The front plate 12FP of the outer stove body 12 is provided with a door that is rotated based on the hinge portion.

The combustion chamber 16 is configured in a cylindrical shape in which the front and rear ends are opened. In the present invention, the combustion chamber 16 has a cylindrical shape. The outer circumferential surface of the combustion chamber 16 is connected to the front end of the plurality of partitions 14 provided on the inner surface of the outer stove body 12. The combustion chamber 16 is maintained at a predetermined interval from the inner surface of the outer hearth body 12 by the plurality of partition walls 14. The spaced inner space between the outer circumferential surface of the combustion chamber 16 and the inner surface of the outer hearth body 12 is formed as an adiabatic space. The inlet of the combustion chamber 16 is connected to the inlet hole of the combustion chamber 16 formed in the front plate of the outer stove body 12. An inlet of the combustion chamber 16 is connected to the front plate of the outer stove body 12. The door 12DR is rotated based on the hinge portion to open and close the inlet of the combustion chamber 16 connected to the external stove body 12 by the door 12DR. Meanwhile, the outlet of the combustion chamber 16 communicates with the rear plate 12RP of the outer stove body 12. The rear end of the combustion chamber 16 has a structure in which the arch is communicated to the rear of the stove 10.

The tubular air inlet 10IH and the heat exhaust outlet 10HP which penetrate the outer stove body 12 communicate with the inside of the combustion chamber 16. Not shown TR is a tray that is slidably coupled to the outer stove body 12 and is disposed below the combustion chamber 16. The ash produced by burning fuel in the combustion chamber 16 is received by the tray TR.

The firewood stove (10) is installed in the firewood (22) under the spheres. The archery 22 is provided at the lower portion of the spheres 24 of the loess ondol, which forms a floor with ocher plate, and the archery stove 10 is installed at the archery 22. A stove coupling hole is formed in the wall WL of the building having a sleeping chamber, and a stove 10 is coupled to the stove coupling hole, so that the inside of the combustion chamber 16 of the stove 10 is secured under the stove. The archery 22 is configured to communicate.

The present invention includes a blower (50) for supplying air to the air inlet (10 IH) communicated with the combustion chamber (16) of the fireplace (10). The blower 50 is disposed outside of the building, the blower 50 is connected to the blower pipe, the blower pipe is passed through the arching 22 under the gudangbang to the air inlet 10IH of the stove 10 Connected. In addition, the blower 50 is provided with an external air intake pipe and an internal air intake pipe, the external air intake pipe communicates with the outside of the goosebang (ocher lodging room) and the internal intake pipe communicates with the inside of the goosebang. The inner intake pipe is connected to the outer intake pipe, and the inside of the inside intake pipe communicates with the inside of the goosebang. In this case, a damper DP is provided at a connection portion between the external intake pipe and the internal intake pipe to adjust the amount of intake air that is drawn into the external intake pipe and the internal intake pipe. A motor is mounted on an outer surface of the connection portion between the external intake pipe and the internal intake pipe, and a damper DP connected to the motor shaft of the motor is embedded in the connection part. The damper DP is rotated by the motor shaft of the motor to adjust the opening and closing degree of the external intake pipe and the opening and closing degree of the internal intake pipe.

The fireplace 10 has a heat supply port in communication with the combustion chamber 16, the heat supply port is connected to the heat pipe 52 embedded in the floor of the room other than the room. At this time, the heat pipe 52 is embedded in a plurality of parallel to the floor of the other indoor room. The bottoms of the plurality of heat pipes 52 are embedded in the longitudinal direction and the transverse direction. A portion of the heat pipe 52 may have a structure connected to the heat supply port of the stove 10 past the arch 22 below the bulb. For example, the heating pipe 52 is embedded in the floor of the living room in the building.

The blower 50 is connected to the air inlet (10IH) of the sub-stove stove 10 via a blower pipe, the inhaler is connected to the blower pipe. The inhaler is installed in a room other than the room. At this time, the filter is built in the inhaler. A filter is built into the inhaler so as to be disposed between the intake pipe part and the intake pipe part of the inhaler.

According to the hot-air combined arch firewood stove system of the present invention, when the fuel burns in the combustion chamber 16 of the stove 10, the heat generated during the combustion of the fuel is secured under the bulbs 24 of the firewood. ) So that the bulbs 24 are covered, so that the heating of the bulbs (rooms of the bulbs 24) can be achieved, and at the same time buried in the floor of an indoor room (eg, a living room) other than the bulbs Since the heat generated from the stove 10 is also supplied to the heat pipe 52, the room 24 other than the compartments 24 may be heated. The heat supply unit 22 is connected to the chimney outside the wall (WL) of the building, it is possible to discharge the smoke and the like.

In addition, through the inhaler installed in the indoor room to supply the outside air to the indoor room can filter the air by the filter to perform the indoor air purification. At this time, the inhaler is connected to the external air supply pipe connected to the air inlet (10IH) of the stove 10 through the inhaler connecting pipe, the motor is connected to the outside of the external air supply pipe or the inhaler connecting pipe, the motor of the motor The damper DP is connected to the shaft connected to the external air supply pipe and the intake connector, and the damper DP is rotated by the rotation of the motor shaft of the motor. Adjust the degree of opening of the internal path of the connector. When the damper DP makes the inner path of the inhaler connecting pipe relatively narrower than the inner path of the outer air supply pipe, and makes the inner path of the outer air suction pipe relatively wider than the inner path of the inhaler connecting pipe, The amount of air supplied to the air inlet (10IH) of the fireplace 10 by the inhaler in the indoor room while the amount of air supplied to the air inlet (10IH) of the stove 10 from the outside of the building is relatively high. Is relatively small, and the damper DP makes the inner path of the inhaler connection pipe relatively wider than the inner path of the outer air intake pipe, and at the same time, the inner path of the outer air intake pipe is compared with the inner path of the inhaler connection pipe. Relatively narrower, the subgut is supplied to the air inlet 10IH of the stove 10 from the outside of the building. That the amount of air supplied to the air inlet (10IH) of the furnace hearth 10 by the other hand in the inhaler interior room being relatively small indoor room air supply amount becomes relatively large with.

In addition, when a dry object such as fruit or laundry is placed on a drying net inside a thermal drying apparatus installed in a heating room (rooms 24), the firewood burns fuel in the combustion chamber 16 of the stove 10. Heat may be raised at 24 so that the object to be dried placed on the drying net of the thermal drying apparatus may be naturally dried.

In addition, the thermo-drying device has a water tank, and when the firewood burns fuel in the combustion chamber 16 of the stove 10, the heat comes up from the balls 24, and the water contained in the water tank is steamed. ) It can function as a humidifier to control the humidity of the interior space of the compartment.

Therefore, the hot air combined firewood fireplace stove system of the present invention has the following effects.

It has the effect of generalizing the expertise of the shipbuilder of the existing heating system. The fire extinguisher 22 is connected to the fire extinguisher 22 underneath the spheres of the bulb (in particular, the bulb 24), the fire extinguisher 10 is connected to the fire extinguisher, and the fire extinguisher 50 is connected to the fire stove 10, and the bulb 24 is housed. It is necessary to install a heat drying device in the room 24 and the inhaler in the room other than the cabin 24, and to install the heating pipe 52 on the floor of the room room other than the cabin 24, the construction of the bed heating system It will have the effect of generalizing its expertise.

Construction management costs are reduced. By reducing the cost of construction and reducing the cost of construction management by generalizing the expertise of the existing heating systems in the old Ondol heating system.

There is a rapid heating function. Due to the characteristics of the ondol, it takes about 3 to 4 hours to light the fire in the ondol room, but the heating time of the indoor surface is shortened to about 30 minutes due to the increase in the internal temperature through the priority heating supply of air in the application of the present invention. . The fire extinguisher 22 under the gourd room may be referred to as a fire arch, and the fire arch may supply a heated air to the fire extinguisher through the stove 10 so that a rapid heating function is possible.

In the room other than the above-mentioned rooms, a heat pipe 52 is provided, and the heat pipe 52 quickly supplies heat to the room floor and the room space of the room, thereby providing a multifunctional heat use system which makes the function of rapid heating more reliable. It is possible to implement.

The present invention is equipped with an indoor and outdoor air intake, the natural principle using the natural convection of the indoor and outdoor air and the covered air of the indoor space is applied to promote the activation of the indoor air flow and the effect of promoting the air flow to the mouth There is. The indoor and outdoor air inlets 10IH may be referred to as internal intake pipes and external intake pipes connected to the blower 50.

On the other hand, the present invention is configured to further increase the heating efficiency by circulating the air around the combustion chamber 16 in the interior of the stove 10 and then supplying warm air to the indoor room of the building requiring heating. In the present invention, the arch is provided with an air circulation assembly in the interior of the stove (10).

The air circulation assembly is provided between the chamber compartment circulating guide partition 14CW provided between the combustion chamber 16 and the external hearth body 12 of the fireplace 10, and between the combustion chamber 16 and the external hearth body 12. And a plurality of circulating guide partition walls. The chamber compartment circulation guide partition wall 14CW and the plurality of circulation guide partition walls are disposed in the radial direction with respect to the center of the combustion chamber 16.

The chamber compartment circulation guide partition wall 14CW physically partitions between the outer circumferential surface of the combustion chamber 16 and the inner surface of the outer stove body 12. At the same time, the front end and the rear end of the chamber compartment circulation guide partition wall 14CW are in contact with the inner surface of the front plate 12FP and the rear plate 12RP of the outer stove body 12.

The plurality of circulation guide partition walls form a through hole between the outer surface of the combustion chamber 16 and the inner surface of the outer hearth body 12. At this time, a plurality of passage holes are alternately formed in front and rear of the stove 10 by the plurality of circulation guide partition walls. In the present invention, it is shown that the four circulation guide partitions in the radial direction with respect to the center of the combustion chamber 16, the four circulation guide partitions are the chamber compartment circulation guide partition wall 14CW, the first circulation guide partition wall ( 14FW), the second circulation guide partition wall 14SW, and the third circulation guide partition wall 14TW.

The outer hearth body 12 of the firewood stove 10 includes a front plate 12FP and a rear plate 12RP, and the outer hearth body 12 has an air inlet 10IH and a heat outlet 10HP, respectively. And the chamber compartment circulation guide partition wall 14CW, the first circulation guide partition wall 14FW, the second circulation guide partition wall 14SW, and the third circulation guide partition wall 14TW. The chamber between the stove bodies 12 is divided into a first circulation chamber 12FCC, a second circulation chamber 12SCC, a third circulation chamber 12TCC, and a fourth circulation chamber 12FCC. In addition, the first circulation guide partition 14FW, the second circulation guide partition 14SW, and the third circulation guide partition 14TW are formed by the first passage hole 12FH, the second passage hole 12SH, and the third. The through hole 12TH is formed.

When the air inlet 10IH and the heat outlet 10HP are provided at a position adjacent to the front plate 12FP of the external stove body 12, the first passage hole 12FH provided in the first circulation guide partition 14FW. ) Is provided at a position adjacent to the rear plate 12RP of the outer stove body 12, and the second passage hole 12SH provided in the second circulation guide partition wall 14SW is the front plate of the outer stove body 12 ( It is formed at a position adjacent to the 12FP, and the third passage hole 12TH provided in the third circulation guide partition wall 14TW is disposed at a position adjacent to the rear plate 12RP of the outer stove sea.

When the air inlet 10IH and the heat outlet 10HP are provided at a position adjacent to the rear plate 12RP of the external stove body 12, the first passage hole 12FH provided in the first circulation guide partition 14FW. ) Is provided at a position adjacent to the front plate (12FP) of the outer stove body 12, the second passage hole (12SH) provided in the second circulation guide partition wall (14SW) is the rear plate of the outer stove body (12). It is formed at a position adjacent to the 12RP, and the third passage hole 12TH provided in the third circulation guide partition wall 14TW is disposed at a position adjacent to the front plate 12FP of the outer stove sea.

Agung, which is the main part of the present invention having the above-described configuration, circulates air into the stove 10 to make it warm, and then supplies the heat to an indoor room requiring heating.

As the fuel injected into the combustion chamber 16 of the fireplace 10 burns, heat is continuously generated from the combustion chamber 16.

Air enters into the first circulation chamber 12FCC of the stove 10 through the air inlet 10IH. The front end and the rear end of the chamber compartment circulation guide partition wall 14CW are formed on the inner surface of the outer stove body 12 of the sub-stove 10 and the outer surface of the combustion chamber 16, the front plate 12FP and the rear plate 12RP. In connection, the air entering the first circulation chamber 12FCC is advanced through the first circulation chamber 12FCC toward the first passage hole 12FH provided in the first circulation guide partition 14FW. Heat exchange with heat generated when fuel is combusted in the combustion chamber 16 while the air coming from the air inlet communicating with the first circulation chamber 12FCC is advanced toward the first passage hole 12FH, that is, the combustion chamber 16. Heat exchange with the air causes the air to turn into heat.

The heat generated by heat exchange of air in the first circulation chamber 12FCC enters the second circulation chamber 12SCC after passing through the first passage hole 12FH provided in the first circulation guide partition wall 14FW. The air converted into heat passes through the first passage hole 12FH provided in the first circulation guide partition 14FW and enters the second circulation chamber 12SCC. The heat introduced into the second circulation chamber 12SCC is advanced toward the second passage hole 12SH formed in the second circulation guide partition wall 14SW while passing through the second circulation chamber 12SCC. The heat from the first circulation hole 12FH into the second circulation chamber 12SCC passes through the second circulation chamber 12SCC and heat exchanges with the combustion chamber 16, so that the heat from the second circulation chamber 12SCC The temperature of the heat in the first circulation chamber 12FCC is higher.

The heat generated in the second combustion chamber 16 enters the third circulation chamber 12TCC after passing through the second passage hole 12SH provided in the second circulation guide partition wall 14SW. The heat introduced into the third circulation chamber 12TCC is advanced toward the third passing hole 12TH formed in the third circulation guide partition 14TW while passing through the third circulation chamber 12TCC. As the heat from the second passage hole 12SH enters the third circulation chamber 12TCC passes through the third circulation chamber 12TCC, the heat is exchanged with the combustion chamber 16, and the heat from the third circulation chamber 12TCC It becomes higher than the temperature of the heat in the 1st circulation chamber 12SCC.

The heat generated in the third combustion chamber 16 passes through the third passage hole 12TH provided in the third circulation guide partition wall 14TW and enters the fourth circulation chamber 12FCC. The heat introduced into the fourth circulation chamber 12FCC passes through the fourth circulation chamber 12FCC and is advanced toward the heat discharge port 10OH provided in the outer hearth body 12. The heat introduced into the fourth circulation chamber 12FCC passes through the heat discharge port 10OH provided in the external stove body 12 while passing through the fourth circulation chamber 12FCC.

Since the heat pipes piped to the floor of the room other than the room of the building is connected to the heat outlet 10OH of the fireplace 10, the heat generated in the fireplace 10 is introduced into the heat pipe, The heating of the indoor room of the building. Since the arch is used as it is for the heating of the indoor room of the building, the heat generated in the stove 10, thereby further increasing the heating efficiency of the building.

On the other hand, the heating pipe 52 is provided with a heating nozzle (52NZ) communicated over the floor of the indoor room, the heat inside the heating pipe 52 can be directly supplied to the indoor room of the building through the heating nozzle, The heating efficiency of the indoor room of the building is further increased.

On the other hand, according to another embodiment of the present invention, the inlet end guide partition wall 14IGW disposed between the chamber compartment circulation guide partition wall 14CW and the first circulation guide partition wall 14FW, and the N-th circulation guide partition wall and chamber A discharge end guide partition 14OGW is further provided to be disposed between the compartment circulation guide partition 14CW, and the chamber between the inlet end guide partition 14IGW and the chamber compartment circulation guide partition 14CW is an inlet end circulation chamber 14ICC. ), And the chamber between the discharge end guide partition wall 14OGW and the chamber compartment circulation guide partition wall 14CW becomes the discharge end circulation chamber 14OCC.

In the present invention, when the arch is viewed from the front end of the stove 10 is shown that the six circulation guide partitions in the radial direction relative to the center of the combustion chamber 16, the hydraulic end circulation guide partition wall and the discharge end guide partition wall. 14OGW is disposed to be inclined, and the sub-combustion stove 10 has a chamber compartment circulation guide partition wall 14CW, a first circulation guide partition wall 14FW, a second circulation guide partition wall 14SW, and a third circulation guide partition wall 14TW) is provided.

In addition, the air inlet portion of the sub-stove provided in the outer stove body 12 of the stove 10 is communicated to the inlet end circulation chamber 14ICC from the outside of the outer stove body 12, the sub-section of the stove 10 The hot air discharge portion provided in the stove body 12 communicates with the inner end end circulation chamber from the outside of the outer stove body 12.

When the air inlet 10IH and the heat outlet 10HP are provided in a position adjacent to the front plate 12FP of the external stove body 12, the inlet end passage hole 14IH provided in the inlet end guide partition 14IGW. Is provided at a position adjacent to the rear plate 12RP of the outer stove body 12, the first passage hole (12FH) provided in the first circulation guide partition wall 14FW is the front plate of the outer stove body (12) ( 12FP) is provided at a position adjacent to the second circulation guide partition wall 14SW, and the second through hole 12SH is formed at a position adjacent to the rear plate 12RP of the outer stove body 12, and the third The third passage hole 12TH provided in the circulation guide partition 14TW is disposed at a position adjacent to the front plate 12FP of the outer stove sea, and the discharge end passage hole 12OH provided in the discharge end guide partition wall 14OGW. ) Is provided at a position adjacent to the rear plate (12RP) of the outer stove body (12).

When the air inlet 10IH and the heat outlet 10HP are provided at a position adjacent to the rear plate 12RP of the external stove body 12, the inlet end passage hole 14IH provided in the inlet end guide partition 14IGW. Is provided at a position adjacent to the front plate (12FP) of the outer stove body 12, the first passage hole (12FH) provided in the first circulation guide partition wall (14FW) is the rear plate of the outer stove body (12) ( 12RP) and a second through hole 12SH provided in the second circulation guide partition wall 14SW is formed at a position adjacent to the front plate 12FP of the outer hearth body 12, and the third The third passage hole 12TH provided in the circulation guide partition wall 14TW is disposed at a position adjacent to the rear plate 12RP of the outer stove sea, and the discharge end passage hole 12OH provided in the discharge end guide partition wall 14OGW. ) Is provided at a position adjacent to the front plate 12FP of the outer hearth body 12.

Air enters the inlet end circulation chamber 14ICC inside the hearth stove 10 through the air inlet 10IH. The front end and the rear end of the chamber compartment circulation guide partition wall 14CW are formed on the inner surface of the outer stove body 12 of the sub-stove 10 and the outer surface of the combustion chamber 16, the front plate 12FP and the rear plate 12RP. Connected, the air entering the inlet end circulation chamber 14ICC is advanced from the air inlet through the inlet end circulation chamber 14ICC to the inlet end passage hole 14IH provided in the inlet end guide partition 14IGW. Heat exchange with heat generated when fuel is combusted in the combustion chamber 16 while the air coming from the air inlet communicating with the inlet circulating chamber is advanced toward the inlet end passage hole 14IH, ie heat exchange with the combustion chamber 16 This is done to turn the air into heat.

The heat generated by heat exchange of air in the inlet end circulation chamber 14ICC enters the first circulation chamber 12FCC through the inlet end passage hole 14IH provided in the inlet end guide partition 14IGW. The air converted into heat passes through the inlet end passage hole 14IH provided in the inlet end guide partition wall 14IGW and enters the first circulation chamber 12FCC. The heat introduced into the first circulation chamber 12FCC is advanced toward the first passage hole 12FH formed in the first circulation guide partition 14FW while passing through the first circulation chamber 12FCC. The heat from the inlet end passage hole 14IH into the first circulation chamber 12FCC passes through the first circulation chamber 12FCC and heat exchanges with the combustion chamber 16, so that the heat from the first circulation chamber 12FCC Higher than the temperature of the heat in the inlet end circulation chamber 14ICC.

The heat generated by heat exchange in the first circulation chamber 12FCC passes through the first passage hole 12FH provided in the first circulation guide partition wall 14FW and enters the second circulation chamber 12SCC. The heat introduced into the second circulation chamber 12SCC is advanced toward the second passage hole 12SH formed in the second circulation guide partition wall 14SW while passing through the second circulation chamber 12SCC. The heat from the first circulation hole 12FH into the second circulation chamber 12SCC passes through the second circulation chamber 12SCC and heat exchanges with the combustion chamber 16, so that the heat from the second circulation chamber 12SCC The temperature of the heat in the first circulation chamber 12FCC is higher.

The heat generated in the second combustion chamber 16 enters the third circulation chamber 12TCC after passing through the second passage hole 12SH provided in the second circulation guide partition wall 14SW. The heat introduced into the third circulation chamber 12TCC is advanced toward the third passing hole 12TH formed in the third circulation guide partition 14TW while passing through the third circulation chamber 12TCC. As the heat from the second passage hole 12SH enters the third circulation chamber 12TCC passes through the third circulation chamber 12TCC, the heat is exchanged with the combustion chamber 16, and the heat from the third circulation chamber 12TCC It becomes higher than the temperature of the heat in the 1st circulation chamber 12SCC.

The heat generated in the third circulation chamber 12TCC enters the fourth circulation chamber 12FCC after passing through the third passage hole 12TH provided in the third circulation guide partition wall 14TW. The heat introduced into the fourth circulation chamber 12FCC passes through the fourth circulation chamber 12FCC and moves toward the third passage hole 12TH formed in the third circulation guide partition wall 14TW. As the heat from the third passage hole 12TH to the fourth circulation chamber 12FCC passes through the fourth circulation chamber 12FCC and heat exchanges with the combustion chamber 16, the heat from the fourth circulation chamber 12FCC It becomes higher than the temperature of the heat in the 3rd circulation chamber 12TCC.

The heat generated in the fourth combustion chamber 16 enters the discharge end circulation chamber 14OCC through the discharge end passage hole 12OH provided in the discharge guide guide partition wall 14OGW. The heat entering the discharge stage circulation chamber 14OCC is advanced toward the heat outlet 10OH. As the heat from the discharge end passage hole 12OH to the discharge end circulation chamber 14OCC passes through the discharge end circulation chamber 14OCC, the heat is exchanged with the combustion chamber 16. Higher than the temperature of the heat in the chamber 12FCC. Heat to the discharge end circulation chamber (14OCC) exits through the heat discharge port (10OH) provided in the outer stove body (12).

Since the heat pipes piped to the floor of the room other than the room of the building is connected to the heat outlet 10OH of the fireplace 10, the heat generated in the fireplace 10 is introduced into the heat pipe, The heating of the indoor room of the building. Since the arch is used as it is for the heating of the indoor room of the building, the heat generated in the stove 10, thereby further increasing the heating efficiency of the building.

At this time, in another embodiment of the present invention, the heat exchange between the combustion chamber 16 and the air by the inlet end circulation chamber 14ICC and the outlet end circulation chamber 14OCC is the inlet end circulation chamber 14ICC and the outlet end circulation chamber. Since 14OCC is not provided more, the heat supply efficiency is increased more by heat exchange.

In summary, in the present invention, the outer stove body 12 is provided with an air inlet 10IH and a heat outlet 10HP, and the first circulation chamber through which the air enters through the air inlet 10IH is a first circulation chamber ( 12FCC), and the circulation chamber partitioned from the first circulation chamber 12FCC by the first circulation guide partition wall 14FW is the first circulation chamber 12SCC and is provided in the first circulation guide partition wall 14FW. The first passage hole 12FH, which communicates the first circulation chamber 12FCC and the first circulation chamber 12SCC, is disposed at a position spaced from the air inlet by a distance from the side when the arch is viewed in one side view of the stove 10. The last circulation chamber through which the heat is discharged through the heat discharge port 10HP is an Nth circulation chamber, and a circulation guide partition wall partitioning the Nth circulation chamber and the N-1th circulation chamber is an Nth circulation guide partition wall. Equipped with the first circulation partition The through-hole which communicates the N-1 th circulation chamber and the N th circulation chamber becomes an N th passage hole, and the N th passage hole is fixed from the said heat exhaust outlet 10HP when the said arch is seen from the other side sectional drawing of the stove 10. At least one circulation guide partition is disposed at a distance from each other and is disposed between the second circulation guide partition 14SW and the N-th circulation guide partition, and the outer surface of the combustion chamber 16 and the outer stove body 12. And a through hole formed in the circulating guide partition wall of the at least one Yixing is the first passage hole 12FH and N of the first circulation guide partition wall 14FW when the arch is viewed in one side cross-sectional view of the stove 10. It is provided in the position shifted | deviated from the Nth passage hole formed in the 1st circulation guide partition wall.

Thus, the air enters the first circulation chamber (12FCC) from the air inlet of the stove 10 and the air passing from the first circulation hole passes through the respective circulation chambers to be heat exchanged to change the heat, the heat is in the hearth stove Come out of the heat outlet (10HP) of (10) can be supplied to the pipe heat pipes in the indoor room of the building. At this time, the air inlet fan is communicated to the air inlet of the firewood stove 10, the outside air is sucked into the air inlet, hot air blowing fan is connected to the heat outlet 10HP of the firewood stove 10, The heat may be configured to supply heat to the inside of the heat pipe from the heat outlet 10HP.

On the other hand, according to the present invention, the heat pipe 52 is built in the spheres 24 to form a heat pipe 53 for the spheres, and the heat contained in the floor of the other room room of the spheres A damper DP is provided between the pipes 52. Specifically, the branch pipe is connected between the heating pipe (53) for the gourd and the heating pipe (52) built in the floor of the other room of the building. In the present invention, the branch pipe is composed of a three-way pipe so as to be connected to the heat exhaust outlet of the stove 22 and at the same time connected to the heat pipe 53 for the spheres and the heat pipe 52. In addition, a damper (DP) is provided in the branch pipe, the damper (DP) is configured to selectively open the heating pipe 53 and the heating pipe 52 for the goose.

The damper DP is connected to a motor shaft of a motor (not shown) to selectively open the gourd heating pipe 53 and the heating pipe 52 according to the rotation of the motor shaft.

When the damper DP is disposed at a neutral position to open the heating pipe 53 and the heating pipe 52 at the same time at the same time, the heat discharged through the heating outlet from the stove 22 is heated in the bulbs. The heat is supplied to both the heating pipe 53 embedded in the ball 24 and the heating pipe 52 embedded in the floor of the other indoor room of the building so that the heating of the heating room and the other indoor room of the building is performed at the same time.

At this time, the hot air is sucked into the warming pipe 53 and the warming pipe 52 by the fan FA connected to the warming pipe 53 for heating and the fan FA connected to the warming pipe 52. (24) and heating by the heating of the floor of the room's interior room, and at the same time to supply the warm air to the room and the indoor room of the building to be heated together.

On the other hand, when the damper DP prevents the warming pipes 53 for the balls embedded in the balls 24, the heat of the stove 22 only by the heat pipes 52 embedded in the floor of the indoor room of the building. Can be supplied.

In addition, when the damper DP prevents the warming pipes 53 for the balls embedded in the floor of the indoor room of the building, only the warming pipes 53 for the balls embedded in the balls 24 of the room. 22) It is possible to supply the heat of the stove.

Therefore, in the present invention, since the degree of opening and closing between the heating pipe 53 for the gourd and the heating pipe 52 of the building indoor room can be controlled by the damper DP, the building indoor room is too hot when the temperature is too high. The damper (DP) can be adjusted to open the piping for the gooseul 24 of the gooseul relatively compared to the heat pipe 52 of the building room room so as not to be too hot in the building room room, the temperature of the room room is too high When the heating room is too hot, the damper DP may open the heating pipe 52 of the building indoor room relatively more than the heating pipe 53 for the heating room of the heating room so that the heating room may not be too hot.

In addition, the chimney 2 is connected to the arching 22 formed below the spheres 24 of the gourd chamber, and a heat circulation tube 102 is further provided at the periphery of the chimney 2, and the warm circulation tube One end of the 102 is configured to communicate with the arch 22 under the spheres 24, and the other end of the heat circulation tube 102 is configured to communicate with the outside air. At this time, the mungryok 22 is provided with a mound (21), the extension of the thermal circulation pipe portion 106 constituting a part of the thermal circulation pipe 102 is embedded to penetrate through the mound (21), the thermal circulation pipe One end of the 102 is configured to communicate with the inside of the arch 22. In addition, the heat circulation pipe 102 is provided with a coiled heat circulation pipe portion 102 disposed on the outer circumferential surface of the chimney 2, the air inlet guide pipe 104 is connected to the coiled heat circulation pipe 102 The end of the air inlet guide tube 104 is disposed below the upper end of the chimney 2, the other end of the heat circulation pipe 102 is configured to communicate with the outside air by the air inlet guide tube 104 do. The lower end of the air inlet guide tube 104 is preferably disposed at a position close to the ground. As a result, a portion of the heat circulation tube 102 is disposed around the chimney 2, and one end of the heat circulation tube 102 communicates with the archery 22 under the spheres 24 and the heat circulation tube 102. Since the other end of the communication with the outside of the building, the interior of the heat circulation pipe 102 takes a structure in communication with the outside of the building 22 and the suburb 22 under the goosebang of the building. Preferably, the inside of the thermal circulation pipe 102 is also configured to communicate with the fan FA. The fan FA communicated with the inside of the warm circulation pipe 102 can more certainly suck the outside air from the air inlet guide pipe 104.

Therefore, the heat comes out together with the smoke from the combustion chamber of the stove (22) stove, and the heat and smoke is partially drawn out of the chimney (2) through the bulb (22), a part of the thermal circulation pipe 102 It is composed of a coil-type hot water circulation pipe portion 102 disposed in the periphery of the chimney (2), the air introduced from the air inlet guide pipe 104 enters the coil-type hot water circulation pipe portion 102 and the chimney ( 2) the heat is switched to heat by heat exchange with the heat discharged to the sub-curve 22 under the spheres 24 while supplying more heat from the sub-curve 22 under the spheres 24. The effect is higher. The waste heat discharged to the chimney 2 is utilized by the thermal circulation pipe 102 to be re-supplied to the fire extinguisher 22 under the bulbs 24 to make the spheres 24 better with the warm spheres 24. Will be given. At this time, there is heat also in the mound 21 itself provided in the archery 22, the extension heat circulation tube portion 106 which is a part of the thermal circulation pipe 102 passes through the mound 21 and then the archery 22 In communication with the interior of the mound (21) itself to utilize even the heat, it is possible to further increase the heating efficiency of the room. Since all the waste heat of the archery 22 is utilized for heating, it is very important that the heating efficiency can be maximized.

In the above, the specific Example of this invention was described above. However, the spirit and scope of the present invention is not limited to these specific embodiments, and various changes and modifications can be made without departing from the spirit of the present invention. Those who have it will understand.

Therefore, since the embodiments described above are provided to completely inform the scope of the invention to those skilled in the art to which the present invention pertains, it should be understood that they are exemplary in all respects and not limited. The invention is only defined by the scope of the claims.

10. Hearth stove 12. Outside hearth body
12FP. Front panel 12 RP. Backplate
12FCC. First circulation chamber 12SCC. 2nd circulation chamber
12TCC. Third Circulation Chamber 12FCC. 4th circulation chamber
12FH. First Passing Hole 12SH. 2nd Pass Hall
12TH. Third Passing Hole 12IH. Inlet end through hole
12OH. Outlet through hole 14CW. Chamber Compartment Circulation Guide Bulkhead
14FW. First circulation guide bulkhead 14SW. 2nd circulation guide bulkhead
14TW. Third circulation guide bulkhead 14IGW. Inlet Guide Bulkhead
14ICC. Inlet end circulation chamber 14OWG. Discharge Guide Barrier
14OCC. Outlet Circulation Chamber 22.
24. Goodies 50. Blowers
52. Heating Piping

Claims (10)

Combustion chamber 16 is provided therein and is installed in the fire extinguisher 22 under the spheres 24, The combustion chamber 16 is a firewood stove 10 communicated with the fire extinguisher 22;
It includes; the bulbs formed on top of the arch 22 by the spheres (24),
The firewood stove 10,
Outer hearth body 12;
A combustion chamber 16 embedded in the outer stove body 12 so as to be spaced apart at a predetermined interval;
The combustion chamber 16 is configured to include a partition 14 for supporting the spaced apart from the inner surface of the outer stove body 12 by a predetermined distance,
Hot air combined firewood stove, characterized in that the inner space spaced apart between the combustion chamber (16) and the outer stove body 12 is formed of a heat insulating space.
The method of claim 1,
And a blower (50) for supplying air to the air inlet (10IH) communicated with the combustion chamber (16) of the fireplace (10).
The method of claim 2,
The blower 50 is provided with an external intake pipe and an internal intake pipe, wherein the external intake pipe communicates with the outside of the bulb, and the internal intake pipe communicates with the inside of the bulb. .
delete The method of claim 2,
A blower is connected to the blower pipe connecting the blower 50 to the air inlet 10IH of the sub-stove stove 10, and the intake unit is installed in a room other than the goosebang, and the intake unit is provided with a filter. The warm air combined use firefighting stove system characterized by the above-mentioned.
The method of claim 1,
The firewood stove (10) is installed in the firewood (22) below the spheres (24), the chimney (22) is connected to the chimney (2), the circumference of the chimney (2) a heat circulation pipe ( 102 is disposed, one end of the heat circulation pipe 102 is in communication with the archery 22, the other end of the heat circulation pipe 102 is combined with the warm air combined with the warm air, characterized in that configured to communicate with the outside of the building Goodbye stove system.
The method of claim 1,
The spheres 24 is composed of ocher spheres, the indoor room with the ocher spheres are ocher guolbang, the warm air, characterized in that the heating pipe 52 is buried in the floor of the room other than the ocher guulbang room Combined firewood stove system.
The method of claim 7, wherein
The heating pipe 52 is a hot air combined firewood fireplace stove system, characterized in that the fan (FA) is connected.
The method of claim 1,
The spheres (24) is composed of ocher spheres, the hot-air combined arch stove gourd stove system, characterized in that the heating pipe for the ocher spheres buried in the ocher spheres.
The method of claim 9,
The hot air dual-purpose firewood fireplace stove system, characterized in that the fan (FA) is connected to the heat pipe (53) for loess.

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