KR101573269B1 - The Manufacture Method Of Heating Room With Fireplace For Moving And It Manufactured Of This - Google Patents

Abstract

The present invention relates to a method for manufacturing a mobile fireplace combined with a movable fireplace combined with a movable fireplace combined with a movable fireplace combined with a movable fireplace, A drying step of a car, a step of applying a heat insulating material, a step of arranging a hot air, a first filling step of loess, a step of installing a wire mesh net, a second filling step of loess, a finishing step of loess and a second drying step, The mobile fireplace combined wall cavity manufactured from the manufacturing method is characterized in that it comprises a mortar layer of cement which is solidified in various forms by a form and solidified to support a total load, a heat insulating material layer which is applied on the mortar layer to block the heat loss chamber, A hot air blower for moving the hot air in a state where the hot air blower is disposed on the layer, a peripheral portion of the hot air blower, A first clay layer which prevents the generation of clearance of the hot air flow which can be caused by the hot air flow and which conducts heat generated from the hot air stream, a second clay layer which is finished in a state of being filled on the first clay layer, A second wire mesh layer provided on the surface of the second yellow clay layer to provide a cohesive force between the first and second yellow clay layers so as to be buried between the first and second yellow clay layers; And a fireplace. Therefore, the present invention can be utilized for container re-installation and container and wood house reshipment by preventing the generation of clearance of the hot air blower, which is a moving passage of the hot air, when the movable fireplace combined-

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a manufacturing method of a portable fireplace combined with a fireplace,

The present invention relates to a method of manufacturing a mobile fireplace combined with a movable fireplace combined with a fireplace and a fireplace combined with a movable fireplace combined with a fireplace installed in a vehicle or a forklift, And a fireplace combined gasket manufactured therefrom.

Generally, traditional Korean spheres are radiant heating system that burns firewood or straw in an oven and sends the combustion air under the floor to the outside through the flue and chimney.

It is a common practice to use firewood in the morning or evening to keep the fire in the fireplace, and then to use it continuously for a certain period of time.

Many of these traditionally styled villas have a lofty bottom to provide relaxation comfort along with the traditional indulgence of emotions, as well as the aura of nature such as loess and charcoal

However, these traditional methods are used only in old houses that have existed since the past, and it is hard to find them at present.

Recently, as a mobile house, a house has been used for a house or a wooden house that has improved the container. However, a position or a clearance for a whale (hot aisle) As required, it was impossible to use the rams immediately after the move.

That is, when moving the gloves, the whale (hot aisle) is deformed or deformed, and workability is required to accurately correct the deformation of the whale after it is moved.

If the whale is used without ignoring the work of correcting the positional change of the whale, smoke or toxic substances generated during the combustion will leak out, making it impossible to use the whale completely.

On the other hand, technologies that have been devised in connection with the Gudangbang are disclosed in Published Unexamined Patent Applications No. 10-2004-0091953, No. 10-0699511, No. 10-0768721, No. 10-1225810, No. 10- 2013-0014824, etc. have been disclosed.

Published Japanese Patent Application No. 10-2004-0091953, Patent No. 10-0699511, Korean Patent Registration No. 10-0768721, Patent No. 10-1225810, Published Japanese Patent Application No. 10-2013-0014824

It is an object of the present invention to overcome the above-described problems, and it is an object of the present invention to provide a portable fireplace combined with a movable house, which can be combined with a house or a wooden house improved in a container exhibited as a mobile house.

In addition, the present invention is characterized in that, after the movement of the hearth, the hearth is directly installed together with the fireplace so that the interior space of the room is warmly guided by the heat transferred to the outside of the fireplace, This makes it possible to simultaneously utilize the surface layer of the floor so that the surface layer is heated quickly.

According to an aspect of the present invention, there is provided a method of manufacturing a mold, the method comprising: a step of forming a mold to solidify the molds into a desired shape; a step of bonding a paper in a mold A mortar step of cementing the mortar layer to form a mortar layer on the paper adhered to the mold, a primary drying step of drying the molten cement mortar layer for a predetermined time period, A step of applying a heat insulating material to form a heat insulating material layer on the mortar layer of the cement so as to block heat loss during a curing process for the layer, and a step of arranging hot air openings as a heat transfer passage on the applied heat insulating material layer A step of arranging the hot air vents, and a step of covering the periphery of the hot air vents and the heat insulating material layer with yellow clay A first filling step of the loess soil forming a first loess layer which prevents the generation of a gap in the hot wind which can be caused in the movement, a step of installing a wire mesh network installed on the first loess layer to improve the cohesion force with the loess, A second filling step of the loess soil which is the uppermost floor layer by filling the loess layer on the first loess layer and the second loess layer by filling the loess layer with the wire mesh network, The method of the present invention comprises the steps of finishing a loess soil to be flattened in a state of flattening the upper surface of the loess layer and drying it for a predetermined time in a cool place for hardening the first and second loess layers, And a secondary drying step in which a fireplace is installed.

The application step of the heat insulating material is a manufacturing method of a mobile fireplace combined with a porcelain material which prevents the generation of toxic gas when a fire occurs and prevents the convection by filling the void between the particles to improve the heat insulating effect. .

The step of arranging the hot air vents may include a step of assembling the hot air vents that each of the hot air vents constituted by the single components are assembled and provided with the hot air vents, and the step of winding the hot air vents into the hot air vents And the foil used in the winding step of the foil is a manufacturing method of a mobile fireplace combined with a foil used as an aluminum material.

In the first filling step of the loess, a pressure-sensitive adhesive is injected into a contact area between the foil and the first loess layer corresponding to the outer surface of the hot wind, and while the hot wind is buried, the loess is injected into the periphery of the hot wind blown on the heat insulating layer And a step of pressing the injected loess to adhere the loess to be filled around the foil using a pressing plate provided on both sides of the hot wind, wherein the adhesive to be injected in the step of injecting loess into the periphery of the hot wind, And the press plate used in the step of pressurizing the injected loess is formed with a plurality of through holes for cohesion with the loess.

The present invention also relates to a mortar layer of cement which is a basic skeleton supporting a total load while being solidified and standardized in various forms by a formwork; A heat insulating material layer applied on the mortar layer to block a heat loss chamber; A hot air blower which is fixed in a state of being disposed on the heat insulating material layer and moves the heat without movement even when moving; A first alveolar layer which prevents heat generated in the hot air flow while preventing generation of clearance of the hot air stream which may be caused when the air is filled and moved on the peripheral region of the hot air stream; A second clay layer which is finishing in a state of being filled on the first clayey so as to become the best bottom layer and receives heat transferred from the hot air to the first clayey so as to transfer heat to users; A wire mesh network embedded between the first and second loess layers to provide cohesion of the first and second loess layers; A fireplace installed on the inflow side of the hot air vents formed in the surface layer of the second loess layer; Wherein a foil of aluminum having a high thermal conductivity is wound on the outer surface of the hot air flow and a pressure sensitive adhesive of a clay pressure sensitive adhesive is injected into a contact portion between the foil and the first clay layer to improve cohesive force, A protruding bar protruding from both sides of the hot air circulation at regular intervals so as to improve the cohesion of the first loess layer on the contact surface between the foil and the first loess layer by closely contacting the first loess layer on the outer surface of the hot air passage in the direction of the foil; A semicircular pressure plate sandwiched between the protruding rods to press-adhere the clay pressure-sensitive adhesive and the first loess layer in a foil direction; And a nut which is rotated in a state sandwiched by the protruding bar to move the pressing plate in the direction of the foil to tighten and fix the pressing plate, wherein a part of the first loess layer passes through the pressing plate, And a movable fireplace combined with a plurality of through holes for enhancing cohesion with the clay soil layer.

And an outlet pipe for discharging the heat to the outside is exposed to the other side of the upper surface of the second clay soil layer, and the outlet pipe for discharging the heat generated from the fireplace installed on the inlet pipe side The heat exchanger is a movable fireplace combined-use room in which the uppermost surface of the hearth is heated and the room air at the same time is converted into heat and the generated fan is installed around the inlet of the inflow pipe so that the generated heat can be forced into the inflow pipe. It is characterized by an example.

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INDUSTRIAL APPLICABILITY As described above, according to the present invention, it is possible to combine fireplaces with fireplaces in a movable manner so that the fireplaces can be moved into a mobile house or a house made of improved wood.

Further, according to the present invention, it is possible to prevent the deformation of the whale (hot passage) during the movement of the firebox combined with the hearth, thereby realizing rapid warming of the hearth after the movement.

In addition, the present invention can increase the overall cohesion force of the hearths during the manufacturing of the combined fireplace in a movable manner, thereby preventing the separation or dropping of some portions (lumps) which may be caused between movements, thereby providing a robust runout.

In addition, the present invention can provide an advantage that users can quickly experience the warmth of the hearth during the manufacture of the combined fireplace furnace.

In addition, since the present invention can eliminate the work of correcting the deformation of the whale (hot passage) after the fireplace combined with the fireplace, the installation of the fireplace can be simplified in addition to the installation of the fireplace. It is possible to provide convenience and promptness to the user.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a block diagram showing a manufacturing method for a portable fireplace combined with a drawbar of the present invention. Fig.
FIGS. 4 to 14 illustrate a method for manufacturing movable fireplaces combined with a movable fireplace on the basis of FIGS. 1 to 3. FIG.
Figs. 15 to 19 illustrate the components of the portable fireplace combined-use hall of the present invention. Fig.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory only and are not restrictive of the limits of scope of the invention, , And should be interpreted based on technical ideas throughout the specification of the present invention.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

As shown in FIG. 1, a method of manufacturing a movable mold cavity according to the present invention includes a mold making step S1, a paper bonding step S2 in a mold, a cement mortising step S3, The step S6 of applying the heat insulating material, the step of arranging the hot wind air S6, the first filling step S7 of the loess, the step of installing the wire mesh netting S8, A filling step S9, a finishing step S10 of loess and a second drying step S11.

Step of making mold (S1)

As shown in FIGS. 1 and 4, the mold making step S1 is a step of fabricating a mold 10 for standardizing and fixing the molds in a predetermined shape. The mold 10 is a rectangular mold, A polygonal shape, or the like.

Of course, the form 10 at this time is formed in a form including not only the frame wall but also the bottom portion. The mold 10 can be used as a wood material.

The paper sticking step (S2)

1 and 5 to 6, when the mold 10 fabricated in the step S1 is in a rectangular shape, the inside of the frame wall corresponding to the inside of the mold 10, To cover the paper 10a.

The paper 10a covers the rim wall and bottom of the formwork 10 to facilitate subsequent separation of the form 10 from the cured cement after the mortar of the cement described below.

Although the figure shows the state in which the paper 10a covers only the bottom portion of the form 10, it can also be covered in the frame wall.

The cement mortar stage (S3)

After the paper is adhered in the step S2, the cement is poured into the mold 10 at a predetermined height, and the upper layer of the cement is evenly coated in a flat state, as shown in Figs. 1 and 7, 20).

The primary drying step (S4)

In step S3, the cement is cured and dried for a predetermined time so as to be fixed.

In the application step (S5)

During the curing process of the cement through the step (S4), as shown in FIGS. 1 and 8, a heat insulating material is laid on the upper layer of the cement, and a flat work is performed on the upper layer of the heat insulating material.

Of course, such a heat insulating material is preferably a non-combustible inorganic material which can provide safety because no toxic gas is generated when a fire occurs, and it has a high heat insulating effect by preventing convection by filling fine particles in the pores between particles to be. Thus, the heat insulating material 30 is formed by spreading the heat insulating material.

Of course, depending on the application, the use of a material other than perlite may also be included.

Arranging the hot air vents (S6)

After the heat insulating material is laid in step S5, the hot air 40 corresponding to the whale is disposed on the upper layer of the heat insulating material layer 30, as shown in FIGS. 1 and 9 to 10.

The arrangement step (S6) of the hot air vents includes the assembling step (S6-1) of hot air blowing and the winding step (S6-2) of the foil as shown in Figs. 2 and 17 with reference to Fig.

The assembling step (S6-1) of the hot air vents is an example of the embodiment shown in the drawing. The hot air vents 40 are assembled in a zigzag manner. The hot air vents 40 form a hollow 40a therein A U-shaped pipe, a U-shaped pipe, and a straight pipe, and they are connected and assembled to have a zigzag-like assembly shape.

Of course, the connecting holes of the hot blast pipes 40 to be connected and assembled as described above are prevented from being separated from each other by using fastening pins, and these fastening pins are fixed to a piece, a nail, a pin or a rivet It is possible to use any fastening means.

The winding step S6-2 of the foil is performed by winding the foil 42 on the outer surface of the zigzag hot air stream 40 completed in the step S6-1 as shown in Fig. .

The foil 42 is preferably made of an aluminum material because it is a material having excellent thermal conductivity and rapidly transfers heat transferred to the inside of the hot air stream 40 to a first clay layer 60 to be described later . In addition, it is also possible to block the harmful substances generated during smoke or combustion that may leak from the connecting portions of the respective hot air vents 40.

The winding process of the foil 42 may be performed by arranging the assembly of the hot wind 40 completely wound with the foil 42 on the upper layer of the heat insulating material layer 30, You may.

The first filling step of loess (S7)

After the step S6, as shown in FIGS. 1 to 3 and 11, the upper layer of the heat insulating material layer 30 including the hot air blast 40 having been placed is primarily filled with yellow earth.

The primary filling step (S7) of the loess includes the step of injecting loess (S7-1) and the step of pressing the injected loess (step S7-2) to the peripheral part of the hot air as shown in FIG.

At this time, in the step of injecting loess into the peripheral part of the hot air flow, the adhesive 50 is injected in order to increase the adhesion of the surface of the hot air 40 and the loess.

The adhesive 50 uses a clay sticker because it improves the efficiency of flocculation on the loess (first loess layer 60) particles.

Particularly, the clay pressure-sensitive adhesive contains properties similar to those of the loess particles, so that they are agglomerated with each other to improve the adhesion of the loess and hot air 40.

In other words, the loess is reduced in viscosity due to moisture evaporation during the subsequent drying step, causing a micro-gap between the loess and the hot wind section to cause a decrease in thermal conductivity. Such a gap problem is supplemented by the above- It is possible to prevent deterioration of the thermal conductivity transferred to the loess (the first loess layer 60) from the second loess layer 40.

The step of pressing the injected loess is performed in order to further prevent the generation of fine gaps between the hot wind 40 and the loess (the first loess layer 60) The first clay layer 60 is pressed against the surface of the hot air 40 by pressing the pressing plate 44 fitted to the protruding rod 43 at regular intervals on both sides of the hot air passage 40, That is, in the direction of the foil 42 wrapping the surface of the hot air vents 40 together with the adhesive 50, thereby preventing the occurrence of gaps which may act as a factor of deterioration of the thermal conductivity.

The pressing plate 44 is fastened by fixing the nut 45 to the screw thread formed in the protruding rod 43. [ That is, tightening force of the nut 45 rotated in the protruding rod 43 realizes close contact and fixing to the pressure plate 44.

After the pressurizing operation of the pressurizing plate 44 against the yellow loess (first loess layer 60) injected together with the injection of the loess (first loess layer 60) into the peripheral part of the hot wind 40 is performed as described above, The first clay soil layer 60 is formed up to the upper layer of the heat insulating material layer 30 including the hot air blast 40 in which the clay is assembled so that there is no flow or fine movement.

Step of installing wire mesh network (S8)

1, the wire mesh network 70 is installed on the first loess layer 60 formed through the step S7, as shown in FIGS. The wire mesh network 70 is provided to enhance cohesion with the clay soil layer. That is, the wire mesh network 70 is buried in the first loess layer 60 and the second loess layer 80 described later, and the first and second loess layers 60, It is possible to provide a cohesive force between them.

Of course, the wire mesh net 70 may be installed at one time, but may be installed two or three times alternately between the first and second loess layers 60, 80 in order to further strengthen the cohesion.

Second filling step of loess (S9)

14, after the execution of the step S8, it is possible to connect the wire mesh network 70 and the first loess layer 70 to the wire mesh network 70 so that the wire mesh network 70 can be buried, 60 to form a second clayey soil layer 80.

The finishing step (S10)

After the second loess layer 80 is formed through the step S9, the dredging operation is performed. That is, it is possible to further enhance the overall cohesion of the first and second clay layers 60 and 80 through the dredging operation.

In addition to the dewatering operation, the upper surface of the second loess layer 80 is planarized.

In the secondary drying step (S11)

After the second loess layer 80 is planarized through the step S10, the first and second loess layers 60 and 80 are dried in a shady place for a predetermined time to harden the first and second loess layers 60 and 80, Once the drying of the molds 60 and 80 is completed, the mold 10 is removed from the molds to complete the manufacturing process for the molds. In addition, when the first and second clayey layers 60 and 80 are dry, a fireplace is installed on the uppermost surface layer of the clayeye, that is, the inlet pipe 41 of the hot airflow 40 formed on the surface of the second clayey layer 80 It becomes possible.

15 to 19, the movable type mold cavity manufactured by the manufacturing method according to the present invention includes a mortar layer 20 that is standardized by a mold, (40) which is fixed on the heat insulating material layer so as to move the heat without movement even when the heat insulating material layer is moved, and a heat insulating material layer (30) A first loess layer 60 for preventing the generation of a clearance of the hot windings 40 which may be caused when the liquid is filled and moved on the heat insulating material layer, A second loess layer 80 that is finished and becomes the best bottom layer and a wire that is buried between the first loess layer 60 and the second loess layer 80 to provide cohesion of the first and second loess layers 60, And a mesh network 70.

Here, the mortar layer 20 is a layer corresponding to the lowermost base frame, and becomes a solidified layer in a state normalized by the mold 10.

It is preferable that the heat insulating material layer 30 is made of a pearlite material, and this pearlite material increases blocking against heat loss in the building material.

That is, the pearlite material is a nonflammable inorganic material, which can provide safety because no poisonous gas is generated when a fire occurs, and the pores between the particles are filled with fine particles to prevent convection, thereby enhancing the heat insulating effect. Thus, the heat insulating material 30 is formed by spreading the heat insulating material. Of course, depending on the application, the use of a material other than perlite may also be included.

On the other hand, the hot air vent 40 is a tubular pipe having a hollow 40a formed therein, and may be arranged in a staggered shape or may be arranged in another form.

For example, when the hot air vents 40 are arranged in a zigzag manner, the hot air vents 40 are assembled by connecting the hot air vents 40. These hot air vents 40 are each composed of a single unit, And has a zigzag arrangement as described above.

16, the hot air vents 40 are provided in various shapes such as a T-shaped tube, a U-shaped tube, and a straight tube, and a specific arrangement is realized by connecting and assembling them, (41) and a discharge pipe (41a) for discharging the heat to the outside. A fireplace (not shown) capable of generating heat can be additionally provided on the inflow pipe 41. An intake fan (not shown) is installed in the inflow pipe 41 to supply heat generated in the fireplace to the inflow pipe 41, .

Accordingly, the heat generated in the fireplace is supplied to the inlet pipe 41 of the hot air vent 40 exposed in the uppermost surface layer of the hearths, that is, the second clay soil layer 80, and passes through the zigzag hot air port 40, It is possible to warm the uppermost surface layer of the room and simultaneously convert indoor air in the room into warm air to obtain a greenhouse effect.

Of course, by using coupling pins (not shown) at the connecting portions of the hot blast pipes 40 connected and assembled as described above, the hot blast holes 40 are prevented from being separated from each other, Or rivets, and the like.

The entire surface of the hot air stream 40 is wound by the foil 42 as shown in FIG. 17 in a state in which the hot air stream 40 is assembled and has a specific arrangement form by the fastening pin. It is preferable to use an aluminum material. Of course, the foil 42 can be used as long as it is made of a material having a high thermal conductivity, which is transferred from the hot air 40 to the clay soil layer.

The foil 42 serves to block not only the heat conduction to the heat transmitted through the hot air vent 40 but also the harmful substances generated during the smoke or combustion that can be flowed out from the respective connecting portions of the hot air vent 40 do.

On the other hand, the first loess layer 60 is buried on the periphery of the hot airflow 40 wound on the foil 42 or on the heat insulating layer 30. At this time, the first loess layer 60, which is filled in the peripheral portion of the hot wind 40, In the case of the clayey layer 60, there is a possibility that a gap is formed at a contact portion between the hot air vent 40 and the first clayey layer 60 due to moisture evaporation during subsequent drying.

18 to 19, a pressure sensitive adhesive 50 is applied to the surface of the foil 42, which is the outer surface portion of the hot air vent 40, and the contact portion of the first clay soil layer 60, In order to increase the adhesion between the surface of the foil 42 and the first clay layer 60.

The pressure-sensitive adhesive 50 uses a clay pressure-sensitive adhesive because it improves the flocculation efficiency of the clay particles (the first clay layer 60).

Particularly, the clay pressure-sensitive adhesive contains properties similar to those of the yellow loess (first loess layer, 60), so that the first loess layer (60) and the foil (42)

In other words, the loess (first loess layer 60) may have low viscosity due to moisture evaporation during subsequent drying, causing a fine gap to the contact area between the loess and the foil 42, which may cause a decrease in thermal conductivity. The gap problem can be compensated with the adhesive 50 to prevent deterioration of the thermal conductivity transferred from the hot air blast 40 to the first yellow clay layer 60. [

The pressure plate 44 provided on both sides of the hot air vent 40 is pressed in the direction of the hot air 40 along with the injection of the pressure sensitive adhesive 50. The pressing plate 44 has a structure in which it is sandwiched between the protruding rods 43 protruding at regular intervals from both sides of the hot air vents 40. The pressing of the pressing plate 44 is rotated in the protruding rods 43, Is caused by the nut (45).

That is, in order to bring the pressure plate 44 into close contact with the adhesive 50 and the first clay layer 60 in contact with the foil 42, which is a peripheral portion of the hot air vents 40, The pressure sensitive adhesive 50 and the first loess layer 60 are further brought into close contact with each other in the direction of the foil 42.

Therefore, the pressure plate 44 further enhances the contact force between the first clay layer 60 and the foil 42 through the adhesive 50.

The pressure plate 44 is provided on both sides of the hot air passage 40. The pressure sensitive adhesive 50 and the first yellowing layer 60 injected into both sides of the hot air passage 40 are concentrated in the downward direction by their own weight, 40 to the foil 42 coated on the outer surface.

That is, the pressure plate 44 has a semicircular shape like the circular pipe of the hot air vents 40, so that the contact pressure between the pressure sensitive adhesive 50 and the foil 42 due to the first alumina layer 60, And the member extending above the semicircular pressing plate 44 has a semicircular shape symmetrical with the semicircular pressing plate 44. This semicircular shape also enhances the cohesive force with the first loess layer 60 . Of course, the semicircular pressure plate 44 may include a semicircular member extending upwardly.

The upper portion of the hot air vent 40 may be injected together with the adhesive 50 and the first yellow clay layer 60. However, due to the first yellow clay layer 60, The pressing plate 44 and the pressure sensitive adhesive 44 need not always be provided on the upper side of the hot air vent 40 because the contact force with the foil 42 wound on the upper side portion is not lowered.

Considering that the shape of the hot air vents 40 is a pipe tube of a circular shape, the pressure plate 44 has a semicircular shape, and the first alveolus layer 60 and the foil 42, It is possible to more easily implement the increase in the contact force.

A plurality of through holes 44a are formed in the pressure plate 44. This allows a part of the first loess layer 60 passing through the through hole 44a to pass therethrough when the pressure plate 44 is pressed, (44) and the first loess layer (60).

As described above, the first loess layer 60 is formed by filling the loess up to the range up to the upper layer of the heat insulating material layer 30 as well as the hot wind 40 assembled while being wound by the foil 42, The hot air vents 40 are kept in a state of being buried by the ventilation openings 60 so that the occurrence of clearance (movement) of the hot air vents 40, which may be caused during the movement of the outdoors, is blocked.

A wire mesh network 70 is installed on the first loess layer 60 and a second loess layer 80 is formed by filling loess on the wire mesh network 70. The wire mesh network 70 includes a wire mesh network 70, And the cohesion between the first and second clayey layers 60 and 80 is enhanced by being embedded between the first and second clayey layers 60 and 80.

On the other hand, the second loess layer 80 is the bottom part of the uppermost layer, which corresponds to the bottom part where the users who use the loess rooms actually make contact, and can feel warmth through the second loess layer 80.

Hereinafter, the operation of the present invention constructed as described above will be described.

The heat generated through the fireplace (not shown) is forcibly sucked toward the inflow pipe 41 by the suction fan (not shown) installed in the inflow pipe 41, moved through the hollow 40a of the hot airflow 40, 41a.

In this process, the heat generated from the hot wind 40 quickly conducts to the first loam layer 60 through the foil 42 wound around the outer surface of the hot wind 40, and the first loam layer 60 As the conduction heat is conducted to the second loess layer 80, the users feel the heat through the second loess layer 80.

In addition, the heat generated through the fireplace (not shown) is introduced into the indoor air of the room, and the indoor air can be converted into the heated air, thereby providing the user with the greenhouse effect.

Such a mobile fireplace combined wall can be used immediately after moving to a place desired by the user, and is particularly useful when applied to mobile containers or mobile wood houses.

This is because the movable fireplace canals can be installed and used immediately after being moved to a desired place because the problem of deformation or minute flow of the whale (hot aisle) position in the moving course is solved.

That is, the hot air vents 40 corresponding to the whale of the goat are installed in the pressurizing plate 44, the wire mesh net 70, or the pressure sensitive adhesive (not shown), which can enhance the cohesive force in a state of being completely buried in the first and second clay soils 60, 42 and the like are configured to prevent the deformation and flow of the hot air stream 40 from being generated during the movement, so that the hot air stream 40 can be immediately used together with the installation of the outlets.

Originally, when positional deformation or flow occurs in the whale of the goat, it is not easy to move the gullies because workability is required to fix this position precisely. Even if the goat is moved, And it was impossible to use swift room because swift work was required to correct the position of whale.

In order to speed up the thermal conductivity, the pressure plate 44 is pressed on both sides of the hot air vent 40 so that the pressure sensitive adhesive 50 and the first loess layer 60 are heated by hot air The wire mesh network 70 and the pressure plate 44 are formed in the wire mesh net 70 and the pressure plate 44 in the direction of the foil 42 wound on the surface of the sphere 40. As a result, And are provided with the through holes 44a. And it is possible to contribute to prevention of heat loss by the constitution of the heat insulating material layer (30).

10: Form 10a: Paper
20: mortar layer 30: insulation layer
40: hot air blower 41: inflow pipe
41a:
42: Foil 43:
44: pressure plate 44a: through hole
45: Nut
50: adhesive agent 60: first clayey layer
70: wire mesh net 80: second loess layer

Claims (7)

A molding step of solidifying the molds in a desired shape;
A paper adhering step in a form in which the paper is adhered to the inside of the mold so that the molds formed in the manufactured mold can be easily separated from the mold;
A mortar step of cementing the mortar layer by pouring the cement into the paper adhered to the formwork;
A primary drying step of drying the mortar cement for a certain period of time for curing to the mortar layer;
Applying a heat insulating material to form a heat insulating material layer on the mortar layer of the cement so as to block heat loss during a hardening process of the cement mortar layer;
A step of arranging hot blast holes for arranging hot blast passages which are heat transfer passages on the applied heat insulating material layer;
A first filling step of the yellow clay forming a first loess layer which prevents the occurrence of clearance of the hot blast which can be caused when the loess is buried by covering the peripheral part of the hot blast and the heat insulating layer;
A step of installing a wire mesh network installed on the first loess layer to improve the cohesion force with the loess;
A second filling step of the yellow loess which is buried in the wire mesh network and forms the second loess layer by filling the loess on the first loess layer to become the top floor;
A step of finishing the loess such that the upper surface of the second loess layer is planarized in addition to the finishing of the second loess layer;
A second drying step of drying the first and second loess layers in a cool place for a predetermined period of time for curing the first and second loess layers, and installing a fireplace on the inflow side of the hot winds formed on the bottom layer surface of the second loess layer;
Wherein the movable fireplaces are combined with the movable fireplaces. The method according to claim 1, wherein the step of applying the heat insulating material comprises:
Wherein the porous material is used as a pervious material for preventing the generation of toxic gas when a fire occurs and for improving the heat insulating effect by preventing particles from being filled in the pores between the particles to prevent convection. The method according to claim 1,
A step of assembling the hot blast holes, which are assembled with the hot blast assemblies constituted by the single components, to provide the hot blast as one assembly; And
And winding the foil, which is wound on the outer surface of the hot air vents constituted by one assembly, to rapidly conduct heat to the inside of the hot air circulation to the clay layer,
Wherein the foil used in the winding step of the foil is made of an aluminum material. 2. The method of claim 1,
A step of injecting an adhesive agent into a contact area between the foil and the first clay layer corresponding to the outer surface of the hot air hole and injecting the clay into the periphery of the hot air blown onto the heat insulating material while burying the hot air hole; And a step of pressing the injected loess to adhere the loess to be filled around the foil by using a pressure plate provided on both sides of the hot wind,
Wherein the pressure sensitive adhesive to be injected in the step of injecting yellow clay into the periphery of the hot air is a clay pressure sensitive adhesive and a plurality of through holes are formed on the pressure plate used in the step of pressing the injected yellow clay to cohesion with yellow soil. Manufacturing method of combined fireplace. A mortar layer of cement which is solidified in various forms by a form and solidified and becomes a basic skeleton supporting a total load; A heat insulating material layer applied on the mortar layer to block a heat loss chamber; A hot air blower which is fixed in a state of being disposed on the heat insulating material layer and moves the heat without movement even when moving; A first alveolar layer which prevents heat generated in the hot air flow while preventing generation of clearance of the hot air stream which may be caused when the air is filled and moved on the peripheral region of the hot air stream; A second clay layer which is finishing in a state of being filled on the first clayey so as to become the best bottom layer and receives heat transferred from the hot air to the first clayey so as to transfer heat to users; A wire mesh network embedded between the first and second loess layers to provide cohesion of the first and second loess layers; A fireplace installed on the inflow side of the hot air vents formed in the surface layer of the second loess layer; Lt; / RTI >
A hot foil of aluminum having a high thermal conductivity is wound on the outer surface of the hot air vents and a pressure sensitive adhesive of a clay pressure sensitive adhesive is injected into a contact portion between the foil and the first clay soil layer,
The clay sticker and the first clay layer are closely contacted with each other in the direction of the foil wound on the outer surface of the hot air passage so as to complement the cohesion of the contact area between the foil and the first clay layer, Protruding rods;
A semicircular pressure plate sandwiched between the protruding rods to press-adhere the clay pressure-sensitive adhesive and the first loess layer in a foil direction;
And a nut that is rotated in a state sandwiched between the protruding rods to tightly fix the pressure plate while moving the pressure plate in the direction of the foil,
Wherein a plurality of through holes for forming a cohesive force with the first alveolus layer are formed on the pressure plate when a part of the first alveolus layer is passed through when pressed by the nut. 6. The method of claim 5,
An inlet pipe for introducing heat is exposed on one side of the upper surface of the second clay soil layer, and a drain pipe for discharging heat to the outside is exposed on the other side of the upper side of the second clay soil layer,
The heat generated from the fireplace installed on the inflow pipe side warms the uppermost surface of the hearth and simultaneously converts the indoor air into the heated air. The hot air is forced to flow around the inflow pipe inlet And a suction fan is installed on the movable fireplace. delete

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