JP2010519439A - Heating structure using dry type hot water heating and its installation method - Google Patents

Abstract

The present invention shortens the implementation period by applying dry construction without giving a load to the building in a dry-type hot water heating structure inside the building and its construction method, and eliminates contracting to a highly skilled workman, and an assembly type construction Through this, it is possible to reduce the impact by minimizing the floor height while blocking the transmission of noise between each layer and enabling rapid heating. After installing a plurality of brackets on the wall while fixing them to the wall at a predetermined interval, an auxiliary bracket is installed on the front of the bracket, an edge frame is installed on the front of the auxiliary bracket, and an upper portion of the edge frame A gypsum board is installed, a shock absorber is installed on the floor, a horizontal beam frame, noise insulation and an underfloor frame are sequentially installed thereon, a heating pipe, an overfloor frame, a charcoal mat panel, an underfloor frame, After the floor of the ondol for water prevention is installed, a finishing frame is installed on the front of the wall, and a finishing cap is installed on the front.
[Selected figure] Figure 1

Description

  The present invention is a dry heating structure and its structure in which the construction of the floor and the vertical wall of the inside of the building is improved by the construction procedure of the structure which can be carried out quickly and reliably without requiring highly skilled workers. It relates to the method of construction, and in particular, by increasing the efficiency of rapid heating and heating, it prevents noise between floors, mitigates the impact, and keeps moisture under the floor by reducing the thickness of the floor It is a thing about the structure of the dry heating using warm water and its construction method which were able to prevent the parasitism of a bad smell and a pest, to be able to construct reliably, and to make the appearance beautiful and beautiful.

  Generally, wet heating using a finishing mortar has the disadvantage that it requires long work time and can not be rapidly heated, as well as requiring skilled work. Recently, dry heating has been used to improve these. As a representative example of dry heating, Korean Patent Application No. 10-2004-58435 by the present applicant has been proposed. Although this proposed technology allows for more rapid heating than wet processing, this conventional technology requires considerable time for heating. Moreover, since an anchor bolt is used for construction, the construction procedure is complicated and the time required for construction increases. Furthermore, in the prior art, not only the noise but also the impact is not alleviated, and in particular, the floor thickness is increased. Furthermore, there is a drawback that the finishing frame is easily displaced by moving upward from the original position.

  The present invention is an improved invention that solves the problems as described above in Korean Patent Application No. 10-2004-58435 filed by the present applicant. Therefore, the object of the present invention is to improve the unreasonable part while maintaining the invention of the prior application, and to support a shock absorber (shock absorber, shock absorber) for keeping the floor level without using anchor bolts. The purpose of this method is to use an adhesive to fix the surface of the body, to reduce the construction period by dry construction, and to block the transmission of noise between floors.

  Another object of the present invention is to facilitate floor construction, minimize floor thickness, ensure sufficient space on each floor, and reduce construction costs.

  Another object of the present invention is to enable quicker and more complete heating by directly transferring the heat dissipated from the floor heating pipe.

  Another object of the present invention is to allow easy installation of Charcoal Mat Panel as well as Geopathic Stress Panel.

  Another object of the present invention is to make it possible to install a finishing material quickly and beautifully by facilitating the construction of a wall surface.

The present invention for achieving the above object is the same as the application of the floor as the applicant's prior application. It is constructed by the dry construction method, and the reference point is set at a predetermined position on the wall surface in the room. The choke line is drawn horizontally based on the reference point. Multiple brackets are fixed to the wall. An auxiliary bracket is provided on the front of the plurality of brackets. An edge frame (edge frame) is provided on the front surface of the auxiliary bracket. A gypsum board is installed at the upper end of each rim. The horizontal beam frame supports the front support fixture of the rim. Shock absorbers are provided for each horizontal beam frame and are arranged along the longitudinal axis of the horizontal beam frame at predetermined intervals that are preset to absorb shock and noise. A soundproof insulation board is provided on the opposite edge corresponding to the lower support fixture near the horizontal beam frame. Most of the underfloor frame is provided on the surface of the horizontal beam frame. A connection piece is provided at the opposite edge of each underfloor frame. The vertical ribs are provided with projections for mounting of the above-floor frame, and the radiant floor panels are provided on each below-floor frame. A heating pipe and an above-the-floor frame are provided on the upper surface of the underfloor frame. On the top of the floor frame, charcoal mat panel, multiple geopathic stress prevention panels (Geopathic Stress Prevention Panel) and multiple radial floor panels (Ondol floor, Radiant Floor Panel) are directed from the bottom to the top It is laminated and provided. And
A finishing frame is connected to the front of each rim and a finishing cap is placed on the front.

  As described above, according to the present invention, the floor surface and the wall surface can be easily and quickly constructed even by a highly skilled worker. As described above, similar to other dry heating systems, the moisture generated on the bottom is removed to prevent the infestation of microorganisms such as mold and maintain the health of the user. Furthermore, the heat dissipated from the heating pipe, which is a heat transfer medium, is directly transmitted to the floor frame. Because of this, the room is heated relatively quickly. In addition, the shock absorber creates a space between the floor surface and the floor material, and at the same time reduces the impact. Thus, since the stuttering generated from the floor material is not directly transmitted to the floor surface, the transmission of the stuttering is prevented, and the stuttering between the floors can be reduced. Furthermore, since the shock absorber is disposed lower than the underfloor frame, the thickness of the floor is relatively reduced, the effective height of each floor can be increased, and the construction cost can be reduced.

  Further, according to the present invention, the end of the floor material is inserted into the lower part of the finishing frame, and the finishing frame and the finishing cap bring about the effect that the interior parts of the building can be beautifully decorated.

It is a disassembled cross-sectional perspective view of the implementation state of this invention. It is sectional drawing which shows the implementation state of this invention. It is sectional drawing which shows the implementation state which shows use of the heating pipe of the implementation state of this invention. It is sectional drawing which shows fixation of the bracket of the implementation state of this invention. FIG. 2 is a perspective view of an auxiliary bracket used in the present invention. It is a wall surface attachment perspective view of the auxiliary | assistant bracket used for this invention. It is a perspective view of the rim of the present invention. It is installation sectional drawing to the wall surface of the rim of this invention. FIG. 1 is a perspective view of a horizontal beam frame used in the present invention. It is installation sectional drawing to the floor of the horizontal beam frame used for this invention. It is sectional drawing of the shock absorber used for this invention. It is an exploded perspective view of a shock absorber used for the present invention. It is an example of installation of the shock absorber used for this invention. It is an example of installation of the noise insulation used for this invention. It is a perspective view of the underfloor frame which installs the heating pipe of the present invention. It is installation sectional drawing of the under-floor flame | frame which installs the heating pipe of this invention. It is sectional drawing which shows installation of the heating pipe of this invention. FIG. 1 is a perspective view of a floor frame used in the present invention. It is installation sectional drawing of the on-floor flame | frame used for this invention. It is installation sectional drawing of the frame on the floor which wrapped the heating pipe of this invention. FIG. 1 is a perspective view of an ondol floor used in the present invention. It is a perspective view of a finishing frame used by the present invention. It is installation sectional drawing of the on-dol floor and finishing frame used for this invention. FIG. 1 is a perspective view of a finishing cap used in the present invention. FIG. 2 is a cross-sectional view of an implementation of the finishing cap installation used in the present invention.

  The embodiments of the present invention will be described in detail with reference to the attached drawings.

  The configuration of the present invention will be described with reference to FIGS. 1, 2 and 3 attached first. A plurality of brackets (A) are fixedly installed on the wall at predetermined intervals. An auxiliary bracket (C) is installed on the front of the bracket (A), and an edge frame (D) is installed on the front of the auxiliary bracket (C). A gypsum board (P) is provided on the top of the rim (D). The horizontal beam frame (H) is installed on the support fixing portion (D-6) on the front surface of the frame (D). On the upper side of the support fixing portion (H-3) below the horizontal beam frame (H), noise insulation (I) between the floors is provided. The shock absorbers (G) are provided under the horizontal beam frame (H), and are arranged at predetermined intervals along the longitudinal direction of the horizontal beam frame (H). An underfloor frame (J) is installed on the upper surface of the horizontal beam frame (H). The opposite edge of each underfloor frame (J) is provided with coupling parts and each underfloor frame (J) is provided with a vertical rib with a projection. A heating pipe (K) and an on-floor frame (L) are installed on the upper side of the underfloor frame (J). A charcoal mat panel (M), a water vein plate (N) and an ondol floor (O) are installed on the upper side of the floor upper frame (L). Ondol floor (O) is provided on the top of the water vein prevention plate (N), and the protrusion (O-1) of each ondol floor (O) is on the upper rib (J-7) of the corresponding underfloor frame (J) Connected, the protrusion (O-1) and the top rib (J-7) are aligned with the depression (O-4) of the adjacent ondol floor (O). After floor construction is completed, the finishing frame (F) is closely bonded to the entire surface of the frame (D). A finishing cap (F-5) is fitted to the surface of the finishing frame (F).

  The partially detailed detailed configuration and implementation method of the present invention thus configured are as follows.

  As shown in FIG. 4, in the bracket (A) made of an iron plate, bolt holes are formed at the top and the bottom, and are normally standardized to 50 mm in length, 12 mm in width, and 5 T in thickness.

  As shown in FIG. 4, a reference point is provided at the lower end of the indoor wall surface. Based on the reference point, horizontal choke lines are drawn on four sides. The bracket (A) is fixed to the wall by a wall mounting bracket (A-1) at a predetermined interval along the drawn choke line.

  The auxiliary bracket (C) is formed with vertical longitudinally extending holes (C-1) as shown in FIG. 5A. The upper fastening recess (cut) (C-2) and the lower fastening recess (cut) (C-3) are respectively formed at the upper and lower portions of the auxiliary bracket (C). The auxiliary bracket (C) is made of non-ferrous metal such as aluminum, for example, and is normally standardized to 50 mm in length, 12 mm in width, and 5 T in thickness.

  As shown in FIG. 5B, each auxiliary bracket (C) is aligned with the longitudinally extending holes (C-1), bolt holes (A-2) formed in the top and bottom of each bracket (A), It is fastened to the corresponding brackets (A) by means of vertical adjustment bolts (B).

  As shown in FIG. 6A, the upper end of the rim (D) is formed with a recess (D-2) on the upper side capable of sandwiching the gypsum board. Fastening fixing part (D-3) and support fixing parts (D-4), (D-5), (D-6) are provided in order from top to bottom on the front face of the frame (D) . The upper fastening fixing portion (D-1) and the lower fastening fixing portion (D-7) are respectively provided on the upper and lower portions of the back surface of the rim (D). The front support fixing portion (D-6) of the rim frame (D) is formed with an insertion hole (D-8).

  As shown in FIG. 6B, the frame (D) aligns the fastening fixing portion (D-3) at the top of the frame (D) with the fastening recess (C-2) at the top of each auxiliary bracket (C), The fastening fixing portion (D-7) at the lower part of the rim (D) is aligned with the fastening recess (C-3) at the lower part of each auxiliary bracket (C) and fixed to the auxiliary bracket (C). At this time, the vertical position adjustment of the rim (D) is performed by tightening or loosening vertical adjustment bolts (B) installed above and below the auxiliary bracket (C). Horizontal position adjustment of the rim (D) is performed by a leveling bolt (E) provided on the support fixing portion (D-6).

  As shown in FIG. 7A, a V-shaped groove (H-1) is formed on the upper surface of the horizontal frame (H). Support fixing parts (H-3) and (H-4) are provided at upper and lower portions on both side surfaces of the horizontal frame (H). Rubber packings (H-2) and (H-5) are provided in the upper and lower support fixing portions (H-3) and (H-4).

  As shown to FIG. 7B, the horizontal beam frame (H) is provided in the support fixing | fixed part (D-6) of the edge frame (D) installed in the wall surface both surfaces, and both. The horizontal beam frames (H) are arranged at predetermined intervals. At this time, a hole for inserting the shock absorber (G) is formed at the center of the horizontal beam frame with a predetermined distance. The horizontal beam frame (H) n inserted shock absorber (G) is installed to support horizontal beam frame (H) to maintain horizontality and to block impact and noise.

  As shown in FIG. 8B, the shock absorber (G) has a lower fastening bracket (G-10), a horizontal adjustment bolt (G-3), a spring (G-6), a (G-7), and a rubber packing. (G-8), (G-5), (G-2), washers (G-9), (G-11), cap (G-4) and nut (G-11) to absorb shock And it is the composition for alleviating.

  As shown in FIG. 8C, the lower fastening bracket (G-10) is fixed to the support surface using an adhesive. At the upper end of the lower fastening bracket (G-10), washer (G-9), packing (G-8), spring (G-7), (G-8), packing (G-5), cap (G) -4) are provided sequentially. And a shock absorber (G) is a horizontal beam frame (H) by the rubber packing (G-2) of the part connected with the horizontal beam frame (H) of the upper end of a cap (G-4) and a washer (G-11) Provided on the lower side of the inner surface of The shock absorber (G) is then assembled with the horizontal beam frame (H) using bolts (G-1).

  At this time, horizontal position adjustment of the horizontal beam frame (H) is performed using a horizontal adjustment bolt (G-3). The springs (G-6) and (G-7) play the role of buffer.

  The rattle insulation (I) is usually made of wood with a thickness of 20 mm, a width of 600 mm and a length of 2400 mm, but other materials with excellent sound absorption and thermal insulation performance may be used.

  As shown in FIG. 9, the rattle insulation (I) is installed on both the lower support fixing portion (H-3) of the horizontal beam frame (H) installed at a predetermined distance on the floor. Ru.

  As shown in FIG. 10A, the underfloor frame (J) includes connecting protrusions (J-14), (J-16) projecting upward from the first edge of the underfloor frame (J), and inserted between them A hole (J-17) is formed, and an insertion bending edge portion (J-2) which is a connecting protrusion which protrudes downward from the second edge of the underfloor frame (J) is formed, whereby Connect the underfloor frame (J). Furthermore, vertical ribs project from the underfloor frame and extend in the longitudinal direction. Furthermore, the assembly fixing portion (J-9) and the fastening fixing portion (J-11) extend in the longitudinal direction, and a coupling hole (J-10) is formed therebetween, and the predetermined position of the first surface of the vertical rib And the underfloor frame (L) and the underfloor frame (J). In addition, the auxiliary rib (J-4) is provided on the second surface of the vertical rib (J-6), and the fastening hole (J) is formed between the vertical rib (J-6) and the auxiliary rib (J-4). -5) is formed.

  Symbols J-3 and J-15 in the figure indicate projections for connecting stubberly.

  As shown in FIG. 10B, the first one of the underfloor frames (J) is provided on the upper side of the horizontal beam frame (H) arranged on the support surface. And the second piece of the underfloor frame (J) is the second piece in the insertion hole (J-17) between the connecting projections (J-14) and (J-16) of the first underfloor frame (J) The inserted bending edge (J-2) of the underfloor frame (J) is connected to the first combined underfloor frame (J) and fastened to the horizontal beam frame (H) using fastening members.

  The XL pipe used as the heating pipe (K) is formed in a coil shape of φ20. As shown in FIG. 11, the heating pipe (K) is fitted to the pipe fixing sheet (J-12) of the underfloor frame (J).

  The floor floor frame (L) includes a bending edge (L-3) bent downward from the first edge of the floor floor frame (L) and the second edge of the floor floor frame (L) as shown in FIG. 12A. And a step-shaped bending edge (L-1) bent twice. A heating pipe groove (L-4) is formed on the lower surface of the floor upper frame (L).

  As shown in FIG. 12B, the stepped bending edge (L-1) of the underfloor frame (J) is between the assembly fixing part (J-9) and the fastening fixing part (J-11) of the underfloor frame (J). It is fitted in the formed coupling hole (J-10). The bending edge (L-3) is then pushed downward, and a fastening hole (J) formed between the vertical rib (J-6) adjacent to the underfloor frame (J) and the auxiliary rib (J-4). -5) is inserted inside.

  The charcoal mat used as charcoal mat panel (M) is formed in a coil shape with a thickness of 1 mm. As shown in FIG. 13, the charcoal mat panel (M) is laid on the floor frame (L) while being laid.

  The copper plate used as the geopathic stress prevention panel (N) is formed in a coil shape with a thickness of 0.3 mm. As shown in FIGS. 13 and 15, the geopathic stress prevention panel (N) is laid over the top of the charcoal mat laid on top.

  A wood panel used as an ondol floor (O) is formed to a width of 200 mm, a length of 800 mm, and a thickness of 10 mm. As shown in FIG. 14, the connecting protrusion (O-1) is formed on the first edge of the ondol floor (O), and the protrusion formed on the second edge of the ondol floor (O) A coupling hole (O-4) is formed between (O-3) and the protrusion (O-5).

  As shown to FIG. 14C, the connection protrusion part (O-1) of each on-dol floor (O) is arrange | positioned at the horizontal upper end (J-7) of the rib of a corresponding under-floor flame | frame (J). The connecting protrusion (O-1) of the ondol floor (O) and the horizontal upper end (J-7) of the underfloor frame (J) are the protrusion (O-3) and the protrusion (O) of the protrusion of the ondol floor (O) It is united in the joint hole (O-4) formed between -5). Ondol floor (O) is installed repeatedly in the same way.

  As gypsum board (P), the board | plate material which has thickness 9.5 mm, width 900 mm, and length 1800 mm can be used, respectively.

  As shown in FIG. 14C, gypsum board (P) is aligned with the gypsum board insertion recess (D-2) of the rim (D).

  The finish frame (F) is beautifully dressed. As shown in FIG. 14B, the insertion grooves (F-1) and (F-2) are formed above and below the front surface of the finishing frame (F). The fastening protrusion (F-4) protrudes from the lower end of the back surface of the finishing frame (F).

  As shown in FIG. 14C, the fastening projection (F-4) of the finishing frame (F) is placed on the fastening and fixing part (D-3) of the corresponding edge frame (D), and the fastening member (F-8) ) Is fixed to the rim (D).

  The surface is beautifully dressed on the finishing cap (F-5). As shown in FIG. 15, in the finishing cap (F-5), insertion edges (F-6) and (F-7) are respectively formed.

  As shown in FIG. 15, the insertion edge (F-6) is inserted into the upper insertion groove (F-1) of the finishing frame (F). And the insertion edge (F7) is provided in the lower insertion groove (F-2), and the finishing cap is pushed downward. Then, the insertion edge (F-7) is fastened to the upper insertion groove (F-1), and the insertion edge (F-7) is aligned in the lower insertion groove (F-2).

  The present invention can be applied to the construction of floor and wall of a building room for improving heating efficiency, preventing noise transmission between floors, realizing an impact absorbing structure, and realizing a quick heating structure. It is.

A Bracket B Vertical adjustment bolt C Auxiliary bracket D Edge frame E Horizontal adjustment bolt F Finishing frame G Shock absorber H Horizontal beam frame I Noise insulation material J Underfloor frame K Heating pipe L Floor top frame M Charcoal mat panel N Water vein prevention plate O Ondol Floor P plasterboard

Claims (15)

The structure of dry-type hot water heating using hot water,
A plurality of brackets (A) fixedly installed on the wall at predetermined intervals;
An auxiliary bracket (C) provided on the front of the bracket (A);
An edge frame (D) provided on the front surface of the auxiliary bracket (C);
A gypsum board (P) provided on the upper part of the above-mentioned rim (D),
A horizontal beam frame (H) provided on the support fixing portion (D-6) on the front surface of the rim frame (D);
Shock absorbers (G) provided at predetermined intervals in the center of the horizontal beam frame (H);
An underfloor frame (J) provided above the horizontal beam frame (H),
A heating pipe (K) and an on-floor frame (L) provided on the upper side of the underfloor frame (J);
A charcoal mat panel (M), a geopathic stress prevention panel (N) and an ondol floor (O), which are laminated in order from the bottom to the top on the upper side of the above floor frame (L), to form a floor surface,
Finishing frame (F) which is joined to the front of the rim frame (D) after construction of the bottom and has a finishing cap (F-5) fitted to the front surface,
A dry hot water heating structure, characterized in that it comprises: In claim 1,
The bracket (A) has bolt holes formed at the top and bottom, and is fixed to the wall surface by the wall mounting bracket (A-1) at predetermined intervals in the width direction of the wall with reference to the horizontal, dry water Heating structure. In claim 1,
The auxiliary bracket (C) has upper and lower longitudinally extending holes by upper and lower fastening recesses (C-2) and lower fastening recesses (C-3) formed at the upper and lower portions of the auxiliary bracket (C). (C-1) is formed, and each vertical adjustment bolt (B) aligned with the hole (C-1) is inserted into the upper and lower bolt holes (A-2) of the bracket (A) A structure of dry hot water heating, characterized in that it is combined with the corresponding bracket (A). In claim 1,
Edge frame (D) is provided with a recess (D-2) on the upper side where gypsum board can be inserted, and on the front surface, from top to bottom, fastening fixing part (D-3) and support fixing part (D4), (D5), (D6) are provided, and upper and lower fastening and fixing portions (D-1) and lower side fastening and fixing portions (D-7) are provided on the upper and lower sides of the back surface. An insertion hole (D-8) is formed in D-6),
The edge frame (D) is aligned with the upper fastening fixing portion (D-3) inserted into the upper fastening recess (C-2) of the auxiliary bracket (C), and the lower fastening recess of the auxiliary bracket (C) (C-3) is combined with the auxiliary bracket (C) by aligning with the upper fastening fixing part (D-7) inserted in (C-3), the position of the rim is for vertical adjustment bolt (B) and horizontal adjustment A structure of dry water heating, characterized by being adjusted by a bolt (E). In claim 1,
The horizontal beam frame (H) has a V-shaped notch (H-1) on the upper surface together with the upper and lower support fixing portions (H-3) and (H-4) on both side surfaces of the horizontal beam frame (H) Rubber packings (H-2) and (H-5) are fitted to the upper and lower support fixing parts (H-3) and (H-4), respectively, and the horizontal beam frame (H) is framed (D) And fixed at both sides of the support fixing portion (D-6), and installed side by side at a predetermined interval, supporting the shock absorber (G) at a predetermined interval in the middle of the horizontal beam frame (H) A dry-type hot water heating structure, characterized in that it is installed to maintain and block shock and noise. In claim 1,
The shock absorber (G) comprises a lower fastening bracket (G-10), a leveling bolt (G-3), springs (G-6), (G-7), rubber packings (G-8), (G- 5), (G-2), washer (G-9), (G-11), cap (G-4) and nut (G-11),
The lower fastening bracket (G-10) is fixed to the support surface using an adhesive
At the upper end of the lower fastening bracket (G-10), washer (G-9), packing (G-8), spring (G-7), (G-8), packing (G-5), cap (G) -4) are provided in order,
The shock absorber (G) is disposed below the inner surface of the horizontal beam frame (H), the rubber packing (G-2) and the washer (G-11) are the upper end of the cap (G-4) and the horizontal beam frame ( H) The structure of the dry-type hot-water heating characterized by being provided in the inner surface. In claim 1,
The rattle insulation (I) is made of a material excellent in noise shielding and heat insulation, and both to the corresponding lower support fixed part (H-3) of the horizontal beam frame (H) installed at a predetermined interval The structure of dry hot water heating, which is characterized by being installed over In claim 1,
In each underfloor frame (J), the underfloor frame (J) protrudes upward from the first edge of the underfloor frame (J), and a connecting projection (J-) having an insertion hole (J-17) formed therebetween. 14), (J-16),
An insertion bending edge portion (J-2), which is a connecting protrusion protruding downward from the second edge of the underfloor frame (J) connected to each other;
The vertical rib protrudes from the underfloor frame, and the vertical rib having the assembly fixing portion (J-9) and the fastening fixing portion (J-11) is a floor top frame (L) at a preset position of the first surface of the vertical rib ) And the underfloor frame (J), and a coupling hole (J-10) is formed between the assembly fixing part (J-9) and the fastening fixing part (J-11), and the vertical rib (J-) 6) and an auxiliary rib (J-4) provided on the second surface, a fastening hole (J-5) is formed,
One of the underfloor frames (J) is placed on top of the horizontal beam frame (H) arranged on the support surface, and the other one of the underfloor frames (J) is placed on the underfloor frame. Of the underfloor frame (J) to be inserted later into the insertion hole (J-17) between the connection projections (J-14) and (J-16), and the tip is bent by the insertion bending edge (J-2) of the underfloor frame (J) A structure of dry water heating, characterized in that it is combined with an underfloor frame (J) laid on the floor and the underfloor frame (J) is fastened with a horizontal beam frame (H) using a fastening member. In claim 1,
A structure of a dry hot water heating, wherein the heating pipe (K) is made of a plastic material and pressed downward and fitted to the pipe fixing sheet (J-12) of the frame (J) under the floor. In claim 1,
The floor floor frame (L) is provided with a bending edge (L-3) which is bent downward one side and a stepped bending edge (L-1) which is folded in two stages on the other side. A heating pipe groove (L-4) is formed in the lower part, and the step-like bending edge (L-1) of each floor upper frame (L) and the assembly fixing part (J-9) of the corresponding lower floor frame (J) Aligned with the coupling hole (J-10) formed between the fastening and fixing portion (J-11), the bending edge (L-3) is pressed downward, and the vertical of the protrusion of the underfloor frame (J) A structure of a dry water heating system, which is inserted into a fastening hole (J-5) formed between the rib (J-6) and the auxiliary rib (J-4). In claim 1,
A structure of a dry hot water heating, wherein a charcoal mat panel (M) and a geopathic stress prevention panel (N) are disposed in order from the bottom to the top on the charcoal mat panel (M). In claim 1,
The ondol floor (O) has a projection (O-1) on one side, and a coupling hole (O-4) is formed between the projections (O-3) and (O-5) on the other side, The protrusion (O-1) of each ondol floor (O) is provided on the horizontal upper end (J-7) of the vertical rib of the corresponding underfloor frame (J), and the protrusion (O-1) of the ondol floor (O) And the upper horizontal end (J-7) of the underfloor frame (J) to the joint hole (O-4) formed between the protrusions (O-3) and (O-5) of the ondol floor (O) Structure of dry-type hot water heating, characterized in that it is adapted. In claim 1,
The surface of the finishing frame (F) is decorated, and the insertion grooves (F-1) and (F-2) are formed at the top and bottom of the front surface of the finishing frame, and the fastening projections (F-4) are below the back of the finishing frame. Protruding, the fastening protrusion (F-4) of the finishing frame (F) is provided on the fastening fixing portion (D-3) of the corresponding edge frame (D), and the finishing frame (F) is an edge frame using the fastening member (D) fixed, characterized in that it has a dry hot water heating structure. In claim 1,
The finish cap (F-5) is decorated on the surface, and the insertion edges (F-6) and (F-7) are formed on the lower side, respectively, and the insertion edge (F-6) is of the finish frame (F) Inserted in the upper insertion groove (F-1), the insertion edge (F-7) is located in the lower insertion groove (F-2), and it is aligned by pressing the finishing cap downward and the lower insertion The structure of a dry-type hot-water heating characterized by being inserted in a ditch (F-2). In the construction method of dry-type hot water heating using hot water,
Setting a reference point on the wall surface and fixing the bracket (A) to be horizontal at a certain height;
Installing the auxiliary bracket (C) on the front surface after the above steps;
After the above steps, a step of closely attaching the rim (D) to the front surface;
After the above steps, shock absorbers (G) are inserted and fixed at predetermined intervals in the middle of the horizontal beam frame (H);
Both the horizontal beam frame (H) is placed on the supporting and fixing part (D-6) of the rim frame (D), and the fixing bracket (G-10) for fixing the shock absorber (G) while arranging and fixing at predetermined intervals Fixing the lower part of the horizontal beam frame (H) to the corresponding insertion hole of the horizontal beam frame (H) by fixing the lower part of the horizontal beam frame (H) with an adhesive;
After the above steps, installing the rattling insulation (I) on the lower support fixing portion (H-3) of the horizontal beam frame (H) to both sides;
Fixing the underfloor frame (J) with the fastening member so as to be orthogonal to the horizontal beam frame (H) after the above steps;
After the above steps, aligning the heating pipe (K) with the pipe fixing sheet (J-12) on the underfloor frame (J);
Securing the floor floor frame (L) to the top of the floor floor frame (J) after the above steps;
After the above-mentioned steps, a geopathic stress prevention panel (N) of the charcoal mat panel (M) is disposed in order from bottom to top on the upper surface of the floor frame (L);
After the above steps, the fastening protrusions (O-1) of the ondol floor (O) are arranged on the horizontal upper end (J-7) of the vertical ribs of the corresponding lower floor frame (J) to obtain the fastening protrusions (O-). 1) aligning the horizontal upper end (J-7) with the joint hole (O-4) of the adjacent ondol floor (O);
Combining the gypsum board (P) with the depression (D-2) formed at the upper end of the rim (D) after the above steps;
After the above process, fixing the finishing frame (F) to the rim (D) using the fastening member;
Connecting the finishing cap (F-5) to the finishing frame (F) after the above steps;
A method of constructing a dry-type hot water heater, comprising:

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