KR20150123445A - Stove with a hot water generation - Google Patents

Abstract

The present invention relates to a stove with a function of generating hot water. More specifically, the present invention relates to a technique to minimize a generation rate of a carbide by minimizing direct contact between a flame, and a water storage box during a process of generating hot water by heating the water storage tank installed in a fire pot. The direct contact between the water storage box and the flame is minimized; and a thermal conductivity for water stored in the water storage tank is improved such that an efficiency for generating hot water can be improved, and an energy consumption rate reduced.

Description

[0001] Stove with a hot water generation [

The present invention relates to a fireplace having a hot water heating function, and more particularly, to a fireplace in which a water storage box is provided on an inner surface of a furnace so that a surface of a water storage box is heated by a flame to heat water therein, As the member is protruded and the inside water is heated by heating and heat conduction of the heat conduction member, the life of the hearth is prolonged by minimizing occurrence of condensation and condensation on the surface of the water storing chamber in the heating process As well as a technique for improving the heating efficiency of water.

Generally used fireplaces are used to burn wood, coal or oil inside the furnace and to heat by using the heat generated in the combustion process.

In recent years, a separate water storage box is installed inside the furnace, and the flame is heated to the surface of the water storage box in the combustion process so that the water in the interior is heated, and the heated water is circulated outside the furnace to generate hot water such as heating water Has been proposed.

However, this conventional technique is a method in which the flame is directly contacted with the water storage box to be heated,

If the temperature of the water contained in the first water storage box before heating such as during the winter season is low, condensation may occur momentarily on the surface of the water storage box during the heating process.

If the heating is continuously performed in the state where the condensation phenomenon occurs, the combustion gas generated during the combustion of the raw material contacts with the liquid at the dew point, and the foreign substance contained in the combustion gas is mixed with the liquid.

In this state, foreign substances mixed with the liquid are pressed on the surface of the water storage box during the evaporation of the liquid, so that a carbonaceous material such as a crud is formed on the surface of the water storage box.

When the heating of the water storage box is repeatedly performed in this form, the carbonized material is piled up as much as it is, so that it is troublesome to remove the carbonated material from time to time and it is not easy to remove the carbonated material.

When the carbonized material is repeatedly piled up, the thermal conductivity of the water in heating the water storage tank is remarkably lowered, resulting in a decrease in hot water generation efficiency, which causes an increase in the amount of fuel used and a correspondingly higher energy loss rate.

Korean Registered Utility Model No. 20-04693580 (2013.09.30)

The present invention has been proposed in order to solve the problems of the prior art,

Basically, in order to minimize the direct contact between the water storage box and the flame in the process of generating hot water through the heating of the water storage box installed in the furnace, the furnace can minimize the generation rate of the carbide.

In order to minimize the direct contact between the water storage box and the flame, the thermal conductivity of the water stored in the water storage box is improved, thereby improving the hot water generation efficiency while reducing the energy consumption rate.

To this end, various embodiments of the present invention,

In a furnace in which a combustion space is formed,

A water storage box which is located on the inner wall surface of the combustion space and in which water is received, is protruded toward the outside in a state where one end of the water storage box is connected to the surface of the water storage box, And a heat conduction member made of a metal which can be heated and can conduct heat to the water in a heating process.

Each of the heat conduction members may be disposed in a shape crossing the outer surface of the water storage box, and one end may be in contact with the water through the water storage box.

The flame is formed upward from the bottom of the heating space, and each of the heat conduction members is horizontally disposed with a vertical gap therebetween. The flame length from the lower end of the water storage box to the upward direction from the water storage box It can be formed short.

And the heat conduction member includes a heating frame which is in contact with the surface of the water storage box, one end of which is in contact with the water through the water storage box, one end of which is in contact with the surface of the fixing frame and protrudes outward can do.

The present invention having these various embodiments,

The part of the flame does not come into direct contact with the water storage box but is contacted with the heat conduction member and the heat conduction member is heated and the water is heated by the heat conduction so that the icing phenomenon on the surface of the water storage box is reduced and thereby the generation of the carbide is suppressed .

Further, since the heat conduction member is disposed in a shape crossing the water storage box, the contact area between the flame and the water storage box is reduced. On the other hand, since the end portion of each heat conduction member passes through the water storage box and is directly in contact with water, Since the heat generated by the water is directly transmitted to the water, the heating efficiency of the water is improved.

In addition, in the structure in which the flame is formed upward from the bottom of the combustion space, each of the heat conduction members is arranged in the upper and lower parts, and the protruding length from the water storage box to the respective heat conduction members disposed upward from the heat conduction member located at the lower end of the water storage box It is also advantageous that each heat conduction member can be brought into uniform contact with the flame.

Further, since the heat conduction member is composed of the stationary frame and the heating frame, the contact area with the flame widens as much as the heat conduction member.

Figure 1 shows a schematic overview of the stove
Fig. 2 is a perspective view showing a water storage box and a heat-
Figs. 3 and 4 are enlarged cross-sectional views illustrating a water storage box and a through-
2,
5 is a schematic view showing a structure in which a heat conduction member is formed in a longitudinal direction
6 is a schematic view of a heat conduction member formed in a curved shape
7 is a schematic view of a heat conduction member in a lattice form
8 is a perspective view showing a fixed frame and a heating frame structure.
9 is a photograph showing a case where no heat conduction member is provided
10 is a photograph showing a state in which the heat conductive member is installed
11 is a schematic view in which a heat-
12 is a schematic view in which the heat conduction member is formed in an oblique direction
Fig. 13 is a schematic view showing a different structure of the through-

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

The stove according to the present invention comprises a stove main body 100, a water storage box 200 and a heat conduction member 300 as shown in Figs.

First, the furnace body 100 has a general stove function, that is, a fuel combustion such as wood or coal to generate heating heat. The furnace body 100 is generally box-shaped and has a combustion space 110 formed therein.

For reference, other structures such as an exhaust port connected to the furnace body 100 can be well known in the art and will not be described further.

At this time, the combustion is performed in a state where the combustion fuel 1 such as wood is placed on the bottom of the combustion space 110 of the stove main body 100, so that the flames generated in the combustion process are discharged from the bottom of the combustion space 110 As shown in FIG.

For reference, the shape and structure of the stove body 100 are not limited to the drawings, and may be variously modified depending on the installation environment, the type of combustion fuel, the size and shape of the water storage box described later, and the like.

The stove main body 100 is provided with a water storage box 200.

The water storage box 200 plays a role of providing a water storage space for heating water by using combustion heat generated in the combustion process of the fuel 1 and at the same time providing a circulation space in circulation to the outside of the heated fireplace main body,

And is disposed in a shape protruding toward the center of the combustion space 110 from the inner wall surface of the combustion space 110 of the hearth main body 100. [

A plurality of water storage boxes 200 may be formed on both sides, rear and top surfaces of the combustion space 110, and the inside of each water storage box 200 may communicate with each other.

In this water storage box 200, water 2 to be used as hot water is accommodated. At this time, a discharge port 210 for circulating the heated water 2 is formed on one side of the water storage box 200, An inlet 220 for introducing the circulated water from the outside into the water storage box 200 is formed.

Therefore, in the furnace having the water storage box 200, basically, the water storage box is heated by the heat generated in the combustion process of the fuel 1, and the water 2 in the interior is sequentially heated by the heat conduction, And then is returned to the outside through the inlet port 210 and then heated again.

In the present invention, a heat conduction member 300 is additionally installed in the water storage box 200 installed as described above.

The heat conduction member 300 serves to minimize the direct contact between the flame and the surface of the water storage box 200 to suppress the generation of the carbonized material due to the freezing and increase the heating efficiency of the water 2,

As shown in FIG. 1 and FIG. 2, a structure of a bar made of metal and protruding toward the center of the combustion space 110 while being connected to the surface of the water storage box 200 .

The heat conducting member 300 may be deformed in various forms,

In the embodiment shown in FIG. 1 and FIG. 2, the heat conductive member 300 is in the form of a rectangular bar and is disposed in such a shape as to cross the outer surface of the water storage box 200 in the horizontal direction, As shown in FIG.

The heat conduction member 300 is installed in such a manner that one end of the heat conduction member 300 protrudes from the surface of the water storage box 200 while passing through the surface of the water storage box 200 and directly contacting the water 2 therein.

At this time, each heat conduction member 300 is formed such that the protrusion length from the water storage box 200 is the shortest and the heat conduction member 300 located at the bottom end of the water storage box 200 is the shortest, ) Are sequentially formed in a long form.

Therefore, as described above, when the flame is formed upward from the bottom of the combustion space, the upper and lower thermal conductive members 300 can all be uniformly contacted with the flame.

Since the thermal conductive members 300 protrude in the vertical direction, the area in which the flames contact the water storage box 200 is minimized, while most of the flames directly contact the thermal conductive members 300.

At this time, the heat conduction member 300 may have a structure in which the space 301 is formed therein as shown in FIG. 3, so that the self-heating time during contact with the flame may be minimized.

Of course, the heat conduction member can be applied to a structure in which the inner space is removed like a round bar as shown in FIG. 4. In this case, the heating speed of the heat conduction member 300 itself is slowed down due to the absence of the internal space, The phenomenon of latent heat is increased, so even if the combustion is stopped, the temperature is not easily lowered and the heating and holding effect is obtained.

The heat conduction members 300 are disposed at upper and lower intervals in a state in which the heat conduction members 300 transverse the water storage box 200 as shown in FIG. And may be configured to be inclined downward toward the opposite end.

In this case, since the flame and the heat can easily flow into the respective heat conduction members 300 when the flame is formed upward from the bottom of the combustion space, the contact ratio between the flame and the heat and each heat conduction member 300 And this has the effect of ultimately improving the heating efficiency of the heat conduction member 300 and water.

Also in this case, each of the heat conduction members 300 may have a space formed therein or a round bar shape.

The heat conduction member 300 must have a structure in which the water storage box 200 is horizontally arranged in a state of horizontally spaced apart from the water storage box 200 as shown in FIG. May be installed.

Also in this case, the heat conductive member 300 can be applied to a structure such as a round bar having no space inside or forming a space therein.

In addition, the heat conduction member 300 may be applied to a structure in which a bent portion is repeatedly formed along the entire longitudinal direction, as shown in FIG. 6, instead of a straight bar shape. The contact area with the flame is increased, which can be accompanied by an effect of improving the heating efficiency of the water 2.

In this case as well, it is applicable both when the heat conductive plug 300 is transverse or longitudinal.

In the above description, the heat conduction members 300 are described as being vertically or horizontally arranged. However, as shown in FIG. 7, the heat conduction members 300 may be arranged in the vertical, Can be implemented.

In this case, the contact area between the flame and the heat conductive member 300 is maximized, while the contact between the flame and the water storage box 200 can be minimized, thereby minimizing condensation on the surface of the water storage box 200 and thereby have.

Also, as shown in FIG. 8, the heat conduction member 300 may be divided into the fixing frame 310 and the heating frame 320 again.

In this case, the stationary frame 310 serves to securely support the heating frame 320 and to transmit the heat of the heat conductive member 300 to the water storage box 200 and the water 2, And one end thereof is installed in contact with the water 2 inside the water storage box 200 through the surface thereof.

The heating frame 320 is also in the form of an elongated bar, and one end of the heating frame 320 is connected to one side of the fixing frame 310 through welding or the like, And is protruded toward the center of the space 110.

Therefore, in this case, since the heating frame 320 and the fixing frame 310 contact the flame at the same time, the heating area is widened accordingly, and the heating efficiency of the water is also improved.

In this case, the arrangement of the heating frames in the process of connecting the heating frame to the fixed frame can be freely arranged in the lateral direction, the longitudinal direction, or the lattice form.

In the above description and corresponding drawings, the heat conductive member 300 is described and illustrated in the form of an elongated bar across the water storage chamber. However, the heat conductive member 300 is not limited thereto, And may protrude from the surface of the water storage box 200 while being in contact with the water 2 through the water storage box 200 at one time.

In the above description, one end of the heat conduction member 300 is described and shown as being in direct contact with the water 2 through the water storage box 200. However, the present invention is not limited to this, May be integrally connected to the surface of the water storage box 200 through welding or the like without passing through the water storage box 200.

Of course, in this case, although the thermal conductivity is lower than that of the structure in which the heat conduction member 300 is in direct contact with the water 2, the effect of suppressing condensation and carbonization can be sufficiently obtained.

Hereinafter, the operation of the present invention based on such a configuration and the unique effects generated in the process will be described.

For reference, in the following description, it is assumed that the embodiment of FIGS. 1 and 2, that is, the heat conduction member 300 has a long bar shape and the water storage box 200 is transversely crossed, For example,

However, the concept that the heat conduction member 300 is integrally connected to the water storage box 200 to minimize the direct contact between the flame and the water storage box and promotes the heating of water through the heat conduction member 300 is also applied to the other embodiments.

First, when fuel is ignited while the fuel 1 is supplied to the bottom of the combustion space 110, the fuel 1 is burned and a flame is generated.

This flame is formed upward from the bottom of the combustion space 110 and each heat conduction member 300 protrudes from the water storage box 200 and is arranged vertically so that each heat conduction member 300 is flame and water So that the direct contact between the storage box 200 is blocked.

Therefore, most of the flames do not come into direct contact with the water storage box 200 and come into direct contact with the respective heat conduction members 300.

In this case, since the protruding length from the water storage box 200 gradually increases as the heat conductive members 300 are arranged in the vertical direction, the entire heat conductive member 300 is uniformly contacted with the flame And can be uniformly heated.

As the direct contact with the surface of the flame and the water storage box 200 is minimized, the condensation phenomenon generated on the surface of the water storage chamber is also reduced when the initial water temperature is lowered and the condensation phenomenon is reduced. The bonding phenomenon between the foreign matter contained therein and the condensation liquid is also reduced, and consequently, the generation of the carbon material by the condensation is minimized.

As each heat conduction member 300 is in contact with the flame, each heat conduction member 300 is simultaneously heated and the internal water 2 is heated as the heat is conducted to the surface of the water storage box 200 during the heating process.

At this time, since the end of each heat conduction member 300 is directly in contact with the water 2 through the water storage box 200, the heat can be directly transferred to the water during the heating of each heat conduction member 300, Even if the direct contact between the water storage box and the flame is reduced, the water heating efficiency by the heat conduction member becomes higher.

As a result of experiments, when the flame is heated directly by contacting with the water storage box without installing the heat conduction member 300, as shown in [Figure 9], the carbonized material in the form of fine particles is formed on the surface of the water storage box 200,

In the case of providing the heat conduction member 300, as shown in FIG. 10, it can be seen that the formation rate of the carbonized material on the surface of the water storage box 200 is remarkably low.

Further, when the heat conduction member 300 was installed and heated by the heat conduction member, the heating temperature of the water was heated to 82 ° C, 93 ° C and 99 ° C at a predetermined time interval from 50 ° C.

On the other hand, when the heat conduction member 300 was not provided, the temperature of the water was heated from 44 ° C to 68 ° C, 83 ° C and 93 ° C when heated under the same time condition as that of the heat conduction member 300.

It can be seen that, when the heat conduction member 300 is installed, the heating efficiency of water is remarkably higher than that of the conventional structure.

Considering that the optimum temperature of the water to be used as the hot water is about 80 ° C, when the temperature is 82 ° C in the state where the heat conduction member 300 is installed, it can be seen that there is a large difference in the hot water generation rate because the conventional technology is 68 ° C.

That is, the present invention minimizes the direct contact between the water storage box 200 and the flame by providing the heat conduction member 300, thereby minimizing the condensation of the water storage box 200 and thus the generation of the carbonized material, The most important feature is that it has effects.

In addition, since the heat conduction member 300 is installed, each heat conduction member 300 interferes with the movement of the heat in the course of the heat of the combustion space being discharged from the combustion space to the exhaust duct, The stagnation time increases, which ultimately causes the heat efficiency of the stove to increase.

Therefore, when the heat conductive member 300 is installed, the temperature of the heat discharged through the exhaust duct is much lower than in the case where the heat conductive member 300 is not installed.

As a result of the experiment, the structure in which the heat conduction member 300 penetrates through the water storage box 200 and directly passes through the water has a temperature of 82 ° C, 93 ° C, and 99 ° C when the heating temperature of the water is checked at intervals of 50 ° C Heated.

On the other hand, the structure in which the heat conduction member 300 protrudes from the surface of the water storage box 200 without passing through the water storage box 200 is heated from 49 ° C to 74 ° C, 91 ° C and 98 ° C .

[Fig. 11] is a view showing still another modification of the present invention,

A heat delaying guide plate 400 is formed in a space above the water storage box 200 located at the upper end of the combustion space 110 so as to protrude from both side walls of the space toward the center,

The heat delay guide plate 400 is positioned in a downwardly inclined form in the process of protruding from both side walls toward each other.

In this state, a hot passageway 410 is formed between the ends of each of the heat delay induction plates 400 and a cylindrical receptacle 500 (see FIG. 4) in which a heating object such as sweet potato can be received is provided at a point above the hot passageway 410 ).

At this time, the water storage box 200 located at the upper part is not a single box form but has a structure in which a partition wall is formed and the heat transfer passage 230 is formed in a zigzag shape.

More specifically, the heat transfer passage 230 is formed in a zigzag shape from the lower end face of the water storage box 200 toward the upper end face.

In this embodiment, the heat generated in the combustion space 110 contacts the surface of the upper water storage box 200 to heat the inside water. In this process, the heat is transferred through the inlet of the heat transfer passage 230 on the lower surface of the water storage compartment And moves in a zigzag fashion along the forming path of the heat transfer passage 230.

As a result, the heat is stagnated in the water storage box 200, so that the time and area of contact with the surface of the water storage box 200 are increased and the heating efficiency of water is improved.

The heat that has passed through the heat transfer passage 230 stagnates between the upper water storage box 200 and the thermal delay guide plate 400 as it collides with the lower surface of the thermal delay guide plate 400.

As the heat stays inside the stove, the heat efficiency of the stove improves accordingly.

The heat stagnant between the heat delay guide plate 400 and the water storage box 200 passes through the hot passages 410 between the heat delay guide plates 400. At this time, As the receptacle 500 is located at the point, the heat generated in the combustion space eventually comes into intensive contact with the receptacle surface.

This increases the heating efficiency of the receptacle, which in turn increases the heating efficiency of the object to be heated located in the receptacle.

[Fig. 13] shows another example of the present invention,

A structure in which the fixed frame 310 penetrates through the water storage box 200 and is in direct contact with water is applied so that a part of the heating frame 320 protrudes locally so that the protruding portion 10 locally penetrates the water storage box In contact with water.

The construction of the penetration structure between the fixed frame 310 and the water storage box becomes much simpler than the structure in which the entire surface of one side of the fixed frame 310 passes through the water storage box.

At this time, the coupling structure between the projecting portion 10 passing through the water storage box 200 and the through hole of the water storage box of the fixed frame 310 is realized by a screw fastening structure or the like, .

1: fuel 2: water
100: furnace body 110: combustion space
200: water storage box 210: outlet
220: inlet 300: heat conduction member
310: stationary frame 320: heating frame
400: thermal delay guide plate 410: hot runner
500: receptacle 230: open passage

Claims (5)

In a furnace in which a combustion space is formed,
A water storage box located on the wall surface in the combustion space and containing water therein,
A metal material protruding outward in a state where one end portion is connected to the surface of the water storage box and disposed to be spaced apart from each other and capable of being heated by contact with the flame in the combustion space and capable of conducting heat to the water during heating; The heat-
And a hot water generating function.
The method of claim 1,
Each of the heat conduction members
Wherein the water storage box is disposed in a shape crossing the outer surface of the water storage box,
A stove with hot water generating function.
3. The method of claim 2,
The flame is formed upward from the bottom of the heating space,
Each of the heat conduction members is disposed horizontally with a vertical gap therebetween, and the protruding length from the water storage box is formed to be longer toward the upper side from the lower end of the water storage box
A stove with hot water generating function.
3. The method according to claim 2 or 3,
The heat-
A fixed frame in contact with the surface of the water storage box, one end of which is in contact with the water through the water storage chamber,
Wherein one end portion is in contact with the surface of the fixed frame and protrudes outwardly,
Containing
A stove with hot water generating function.
3. The method of claim 2,
The flame is formed upward from the bottom of the heating space,
Each of the heat conduction members is horizontally disposed with a vertical interval therebetween. The heat conduction member is inclined downward from a side end portion connected to the water storage box toward an opposite end side
A stove with hot water generating function.

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