KR102163271B1 - The Method of Building by Using Masonry Wall Panel Modules with Wedge-Shape Joint Blocks and Frames - Google Patents

Abstract

The present invention relates to a building construction method using masonry wall panel modules having blocks and frames with wedge type joints, which forms the masonry wall panel modules by inserting a plurality of blocks having wedge type protrusions or concave grooves over the entire surface of upper, lower and side surfaces into frame modules having wedge type concave grooves or protrusions at an inner side surface and fixes the premanufactured masonry wall panel modules by fastening members after coupling the same to slabs and columns in a construction site, thereby easily constructing a wall of a building using a masonry structure and improving stability of a structure.

Description

The Method of Building by Using Masonry Wall Panel Modules with Wedge-Shape Joint Blocks and Frames

The present invention relates to a masonry wall that forms a wall of a building by stacking blocks such as bricks, and more particularly, a wedge-shaped protrusion or a wedge-shaped protrusion across the upper and lower surfaces and side surfaces of a frame module in which a wedge-shaped recess or protrusion is formed on the inner surface. A masonry wall panel module is formed by inserting a plurality of blocks with concave grooves, and the masonry wall panel module completed in advance is connected to the slabs and columns at the construction site and then fixed with a fastening member, thereby facilitating the wall construction of a building with a masonry structure. , It relates to a building construction method using a masonry wall panel module composed of a block and a frame with a wedge-shaped coupling part to improve the stability of the structure.

In general, a building to which a conventional construction method such as a reinforced concrete structure or a brick masonry structure is applied has a complicated construction process, requiring a lot of manpower to be invested in the construction of the building, and the construction period is lengthened, resulting in an increase in construction expenditure.

In particular, according to the conventional construction method, in the case of small-scale buildings such as detached houses, the construction cost increases compared to the size of the completed building, so construction productivity is further lowered, and maintenance and remodeling work due to defects occurring after the construction of the building is completed is difficult. Had a difficult problem

Therefore, in recent years, a prefabricated building construction method in which a building is constructed by assembling a prefabricated building component module at a construction site is gradually spreading.

Such a prefabricated building, like the prefabricated building module disclosed in Korean Patent Publication No. 10-1086060 (registered on November 16, 2011), is formed by combining columns, beams, and panels to form the walls and slabs of the building.

Since prefabricated buildings form a building by assembling prefabricated modules at the construction site, the construction cost of small-scale buildings can be reduced, and by performing module replacement only for areas requiring repair or remodeling, maintenance and repair Make remodeling work easier.

However, in the case of the existing prefabricated building module that combines columns, beams, and panels, due to the characteristics of the panel made of plate, the noise generated when impacting the walls and slabs applied to the module is easily transmitted to the interior space, causing inter-floor noise. Can be.

And, after the module manufacturing process and the completion of the building, several panels are combined to form a wall or slab to form a wall or slab, which causes the strength, waterproofing, and windproof performance to deteriorate at the bonding surface between each panel. In the event of an earthquake, the walls or slabs may collapse as the panels fall off due to damage to the bonding surfaces between panels, resulting in a safety accident.

In order to solve this problem, in the wall structure using blocks and frames with wedge-shaped joints disclosed in Korean Patent Publication No. 10-1861837 (registered on May 21, 2018), walls compared to prefabricated building modules in which panels are applied using masonry blocks. It effectively suppresses the transmission of noise generated by the impact on the wall, and greatly improves the durability and seismic performance of the wall through the wedge-shaped coupling surface between the frame and the block.

However, in the case of a wall structure using the above wedge-shaped joint block and frame, the block cannot be stacked at the top of the frame due to the interference of the block and the protrusion of the wedge-shaped joint formed on the frame when the block is mounted inside the frame. The process of installing the finished frame member must be added, and the masonry process took a lot of time in the process of stacking blocks inside the frame at the building construction site, which greatly increased the construction period. There was a problem that it was difficult to improve the construction productivity, such as an increase in construction cost due to the need to input manpower.

Republic of Korea Patent Publication No. 10-1086060 (registered on November 16, 2011) Republic of Korea Patent Publication No. 10-1861837 (registered on May 21, 2018)

In an embodiment of the present invention, a wall panel using a masonry block is modularized to assemble a prefabricated masonry block module at a construction site to construct a building, thereby improving the ease of construction and shortening the construction period of the building to which the masonry block is applied. It is aimed at.

In an embodiment of the present invention, by improving the waterproof and windproof performance on the bonding surface of the masonry wall panel module, housing convenience is improved, and by improving the strength of the bonding surface between blocks of the masonry wall panel module, safety due to the collapse of the wall in the event of an earthquake. It aims to prevent accidents.

In an embodiment of the present invention, an object of the present invention is to prevent the generation of inter-floor noise by enhancing the sound-absorbing performance of the wall compared to the existing prefabricated building module using a panel that is vulnerable to noise and vibration transmission.

According to an embodiment of the present invention, the present invention provides a first horizontal frame having a V-shaped or W-shaped wedge-shaped concave groove over the entire lower surface according to the size of the wall of a building on which slabs and columns are pre-installed, A frame for cutting a second horizontal frame with a V-shaped or W-shaped wedge-shaped protrusion over the entire upper surface and a vertical frame with a V- or W-shaped wedge-shaped protrusion or wedge-shaped concave groove over the entire inner surface A frame fixing the first horizontal frame or the second horizontal frame and the vertical frame connected to both ends of the first horizontal frame or the second horizontal frame with a frame fastening member during the module cutting process A block masonry in which a block with V-shaped or W-shaped wedge-shaped protrusions and wedge-shaped concave grooves is inserted into the frame connected to the first assembly step of the module and across the upper surface and the front of one side and the lower and the other side. A masonry consisting of a second assembly step of a frame module connecting the first horizontal frame or the second horizontal frame to the open end of the vertical frame and then fixing it with a frame fastening member to form a wall masonry wall panel module. The masonry wall panel module that forms a wall by fixing the wall panel module manufacturing process, the masonry wall panel module transport process, the frame module of the masonry wall panel module) to the slab or pillar of the building. It consists of a construction process, but during the construction of the masonry wall panel module, a complementary staircase or wedge-shaped wall module coupling surface is formed at the vertical frame or the first and second horizontal frame connection portions of the frame module to connect a plurality of wall panel modules to each other. A construction method using a masonry wall panel module composed of a block and a frame with a wedge-shaped coupling part, characterized in that it includes the step of connecting the masonry wall panel module, which is a process of forming a wall by fixing the connection between the frame modules with a fastening member after connection. to be.

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According to an embodiment of the present invention, the frame module is formed such that two or more rows of wedge-shaped concave grooves or wedge-shaped protrusions are arranged, and a block having a V-shaped wedge-shaped protrusion and a wedge-shaped concave groove is formed in the block masonry step. A block with a W-shaped wedge is inserted into the frame module, or a wedge-shaped protrusion and a wedge-shaped concave groove are arranged in two rows, and a V- or W-shaped wedge-shaped protrusion and a wedge-shaped concave groove are formed. Both types of silver may be mixed, or any one type may be selected and mounted on the frame module and fitted.

According to an embodiment of the present invention, in the manufacturing process of the masonry wall panel module, in the first assembly step of the frame module, one end of the vertical intermediate frame is connected to the inner center of the first horizontal frame, and the second horizontal frame is assembled in the second assembly step of the frame module. A process of connecting the other end of the vertical intermediate frame to the inner central portion of the frame may be added, or a process of connecting the horizontal intermediate frame to the inner central portion of each vertical frame in the block masonry step may be added.

According to an embodiment of the present invention, a chassis serving as a window frame or door frame is formed on an intermediate frame in a vertical or horizontal direction, and a process of mounting a window or door to the chassis may be added after the masonry wall panel module construction process is completed.

According to an embodiment of the present invention, at least one coupling groove and a coupling pin having a complementary shape are formed on each of the wall module coupling surfaces to be coupled to each other, and a process of inserting and connecting the coupling groove and the coupling pin during the construction of the masonry wall panel module, and A process of inserting a sealing member between the wall module coupling surfaces and a process of attaching a protective cap to a fastening groove into which the fastening member is inserted are added.

According to an embodiment of the present invention, one or more hooks and hook grooves are formed so as to form a complementary shape between the wall module coupling surfaces that are coupled to each other, and before fixing through a fastening member between masonry wall panel modules connected to each other in the masonry wall panel module construction process. , A process of temporarily fixing a hook and a hook groove may be added.

According to an embodiment of the present invention, in the block masonry step, a process of burying an insulation material or a heating wire inside the masonry wall panel module may be added.

According to an embodiment of the present invention, the process of burying a pipe in which water pipes, electric wires, or communication lines are installed inside the masonry wall panel module in the block masonry step, and an electric outlet built in some blocks of the masonry wall panel module are connected to the wires in the pipe. A connecting process is added.

According to an embodiment of the present invention, after the construction process (S40) of the masonry wall panel module 10, a process (S60) of installing the partition module 300 serving as a partition for dividing the indoor space of the constructed building is added,

In the process of installing the partition module, the side wedge-shaped protrusion surfaces between a plurality of blocks are bonded to each other to be connected, or a wedge-shaped protrusion and a wedge-shaped concave in the shape of V or W are formed on each wedge surface of the partition frame in which the wedge-shaped joint is formed. A partition module unit may be formed by bonding and connecting wedge-shaped concave grooves or wedge-shaped protrusions between a plurality of blocks with grooves formed thereon, and each partition module unit may be stacked to a designed partition height to form a partition module.

According to an embodiment of the present invention, after the process of installing the partition module is completed, a process of installing a vertical frame and a fastener having a wedge-shaped corner is added to the partition module, but the vertical frame is V at the outermost part of the stacked block of the partition module. It is installed in a wedge-shaped protrusion and a wedge-shaped recess of a ruler or W-shape, and the fixture may be installed along the height direction of the partition module on the side surface of the connecting portion between the stacked blocks of the partition module. .

According to an embodiment of the present invention, a bracket on which a shelf or table plate is mounted is formed on the vertical frame or block surface of the masonry wall panel module, and after mounting the shelf or table plate to the bracket during the masonry wall panel module construction process, A process of fixing the bracket and plate with a fastening member is added.

According to an embodiment of the present invention, a bracket on which a plate of a shelf or a table is mounted is formed on the side surface of a vertical frame or a fixture of the partition module, and after mounting the plate of the shelf or table to the bracket in the process of installing the partition module, the bracket A process of fixing the and plate with a fastening member may be added. .

According to an embodiment of the present invention, a masonry wall panel module formed by masonry blocks inside a frame is manufactured in advance and then transported to a construction site and then assembled, thereby reducing the time required for masonry block masonry of the masonry wall panel module at the construction site. Thus, there is an effect of reducing the construction time and reducing the labor cost of constructing the masonry wall of the building by omitting the masonry construction requiring a large number of manpower, thereby reducing the construction cost of the masonry structured building.

According to an embodiment of the present invention, the rigidity and durability of the masonry wall panel module are improved by the combination of the wedge-shaped protrusions and concave grooves formed in the frame module and the block, and the seismic performance is greatly improved compared to the existing buildings to which the masonry structure vulnerable to earthquakes is applied. There is an effect that can be improved.

According to an embodiment of the present invention, it is possible to facilitate the separation and replacement of blocks from each masonry wall compared to a building to which a conventional masonry structure is applied, thereby facilitating maintenance and remodeling work after completion of the building.

According to an embodiment of the present invention, by preventing separation between the block and the frame through the combination of the wedge-shaped protrusion and the concave groove formed in the frame and the block, the strength of the wall is improved compared to the panel used in the existing modular building, and There is an effect of improving the convenience of residence after completion of the building by preventing the occurrence of ringing when an external shock is applied.

According to an embodiment of the present invention, when constructing a wall of a building by combining the masonry wall panel module, it is possible to more easily perform a process of mounting a window or door to the wall through a chassis formed in an intermediate frame.

According to an embodiment of the present invention, the bonding surface formed between the masonry wall panel modules to be combined with each other is formed in a step or wedge shape of a complementary shape to increase the contact area between the masonry wall panel module bonding surfaces, thereby waterproofing, windproofing and insulating the constructed building. There is an effect that can improve performance.

According to an embodiment of the present invention, it is possible to improve the waterproof, windproof and thermal insulation performance of the constructed building through the coupling of the coupling groove of the complementary shape formed on the coupling surface between the masonry wall panel modules and the coupling pin and the sealing member inserted into the coupling surface. It can have an effect.

According to an embodiment of the present invention, corrosion is prevented as rainwater flows along the fastening surface of the fastening member through a protective cap mounted in the fastening groove into which the fastening member is inserted, and the fastening member is not exposed to the outside of the building. This has the effect of improving the aesthetics of the building.

According to an embodiment of the present invention, the separation between the masonry wall panel modules in a temporary bonded state during the wall construction process is prevented by fitting a hook and a hook groove formed in a complementary shape formed on the bonding surface between the masonry wall panel modules, There is an effect of making it easier to fix the masonry wall panel module through the member.

According to an embodiment of the present invention, water pipes, electric wires, or communication lines are installed in the piping buried inside the masonry wall panel module to shorten the construction period for installing water pipes, etc., and to reduce construction costs, and masonry There is an effect that the installation location of the outlet can be easily adjusted through the electric outlet built in some blocks of the wall panel module.

According to an embodiment of the present invention, there is an effect of improving the insulation performance of a building constructed through the masonry wall panel module through an insulation material or a heating wire embedded in the masonry wall panel module, and preventing the occurrence of condensation on the wall in cold weather.

According to an exemplary embodiment of the present invention, there is an effect of easily dividing and forming an indoor space of a constructed building through a partition module installed inside the building.

According to an embodiment of the present invention, a bracket on which a shelf or a table plate is mounted is formed on a surface of a masonry wall panel module or partition module, so that the shelf or table can be easily installed on an indoor wall after construction is completed.

According to an embodiment of the present invention, by forming a pattern on the wall by arranging blocks of different colors or materials during the manufacturing process of the masonry wall panel module, there is an effect of improving the aesthetics of the constructed building.

1 is a view showing the overall configuration of the masonry wall panel module and each member of the masonry wall panel module composed of a block and a frame having a wedge-shaped coupling part according to an embodiment of the present invention.
2 is a view showing a wall structure formed by mounting a masonry wall panel module according to an embodiment of the present invention to a slab and a column of a building, and a cross-sectional structure of the wall.
3 is a view showing a perspective view, a front view, a side view, and a plan view according to an embodiment of a block constituting the masonry wall panel module of the present invention.
FIG. 4 is a plan view illustrating an example of combining blocks in a frame in a masonry wall panel module composed of a block and a frame with a wedge formed in a V or W shape according to an embodiment of the present invention.
5 is a view showing the configuration of each member of the masonry wall panel module in which an intermediate frame is formed according to an embodiment of the present invention.
6 is a plan view showing an example of a chassis structure formed on an intermediate frame of a masonry wall panel module according to an embodiment of the present invention.
7 is a view showing a structure of a joint surface between frame connection parts of a masonry wall panel module according to an embodiment of the present invention.
8 is a diagram illustrating a modified embodiment of a structure of a joint surface between frame connection portions of a masonry wall panel module installed at a wall edge of a building according to an exemplary embodiment of the present invention.
9 is a view showing a modified embodiment of a structure of a coupling surface between frame connection parts of a masonry wall panel module installed in a central part of a wall of a building according to an embodiment of the present invention.
10 is a plan view showing an example of a hook and hook groove structure formed on a mating surface between masonry wall panel modules according to an embodiment of the present invention.
11 is a plan view illustrating an example of space utilization formed between blocks mounted inside a frame module of a masonry wall panel module according to an embodiment of the present invention.
12 is a side view showing an example of a structure for fixing a shelf or a plate of a table to a masonry wall panel module using a bracket according to an embodiment of the present invention.
13 to 16 are plan views illustrating a modified embodiment of a partition module structure according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings.

It will be described in detail focusing on the parts necessary to understand the operation and operation according to the present invention.

In describing the embodiments of the present invention, descriptions of technical contents that are well known in the technical field to which the present invention pertains and are not directly related to the present invention will be omitted.

This is to more clearly convey the gist of the present invention by omitting unnecessary description.

In addition, in describing the constituent elements of the present invention, different reference numerals may be assigned to constituent elements of the same name according to the drawings, and the same reference numerals may be denoted even in different drawings.

However, even in such a case, it does not mean that the corresponding component has different functions according to the embodiment, or that it has the same function in different embodiments, and the function of each component is the corresponding embodiment. It should be determined based on the description of each component in

In addition, the technical terms used in the present specification should be interpreted in the meaning generally understood by those of ordinary skill in the technical field to which the present invention belongs, unless otherwise defined in this specification. It should not be construed as a meaning or an excessively reduced meaning.

In addition, the singular expression used in the present specification includes a plurality of expressions unless the context indicates otherwise.

In the present application, terms such as "consist of" or "include" should not be construed as necessarily including all of the various elements or various steps described in the specification, and some of the elements or some steps It may not be included, or it should be interpreted that it may further include additional elements or steps.

A structure of a masonry wall panel module composed of a block and a frame in which a wedge-shaped coupling part is formed according to an embodiment of the present invention will be described as follows.

The structure of the masonry wall panel module of the present invention is at both ends of the first horizontal frame 110 and the second horizontal frame 120 and the first and second horizontal frames 110 and 120 arranged parallel to each other as shown in FIG. A plurality of blocks 200 are masonry and fitted inside the frame module 100 consisting of a vertical frame 130 connected to the masonry wall panel module 10.

The first horizontal frame 110 has a V-shaped wedge-shaped groove formed over the entire lower surface, and the second horizontal frame 120 has a V-shaped wedge-shaped protrusion over the entire upper surface, A V-shaped wedge-shaped protrusion or a wedge-shaped concave groove is formed over the entire inner surface of the vertical frame 130.

In addition, the block 200 has a V-shaped wedge-shaped protrusion and a wedge-shaped concave groove formed over the upper surface and the front surface of one side, and the lower surface and the other surface as shown in FIG. 3A or 3B, Each of the wedge-shaped protrusions and the concave grooves are formed at the same angles as each other so that the wedge-shaped protrusions or concave grooves formed in the frame module 100 can be coupled in close contact with the wedge-shaped concave grooves or protrusions of the block 200.

The wedge-shaped protrusion or the concave groove of the block 200 is inserted into the wedge-shaped protrusion or the concave groove of the frame module 100, respectively, and the wedge-shaped protrusion and the concave groove of the block 200 constructed adjacent to each other are connected to each other. ) Is firmly fixed to prevent the block 200 from being separated from the masonry wall panel module 10 that has been assembled.

At this time, even if the movement of the block 200 occurs due to a strong external force caused by an earthquake or the like on the wall of the building formed by the masonry wall panel module 10, the vertical force caused by the self weight of the block 200 acts and Since the block 200 returns to its original position along the wedge-shaped slope of the shape, the wall strength and seismic performance of the building constructed through the masonry wall panel module 10 can be further improved.

In addition, the V-shaped wedge-shaped protrusion or concave groove prevents the connection between the frame and the block 200 from being able to be connected only in a specific direction while directionality is generated in the connection process, so as to further improve assembly. It is desirable to achieve the wedge angle of an isosceles triangle shape.

The masonry wall panel module 10 is produced before input to the construction site by assembling the frame module 100 cut according to the size of the wall surface of the building to be constructed and by mounting the block 200 inside the frame module 100 It is produced and completed in advance at a factory, and as shown in FIG. 2, by placing the masonry wall panel module 10 transferred to the construction site on the slab 1 and the column 2 and fixing it with a fixing member 11 , Block 200 is to construct a wall of a building made of a masonry structure.

Each wall can be configured to connect two or more masonry wall panel modules 10 in a horizontal or vertical direction and then fix it with a fastening member 146, and each combined masonry wall panel module 10 is a constructed building The walls of the building are partitioned.

The division of the wall is more efficient by separating and replacing only the masonry wall panel module 10 of the corresponding division that requires repair when a defect occurs or maintenance is required after the construction process or construction of a building is completed. Make it easy to perform.

Through this, the construction time is shortened by reducing the time required for the connection of each frame and the masonry construction of the block 200 at the building site, and the labor cost is reduced by reducing the manpower input for the masonry construction of the block 200 It is possible to reduce the construction cost of the building.

At this time, the vertical frame 130 or the first and second horizontal frames 110 and 120 of the masonry wall panel module 10 connected to each other have a complementary shape of a staircase or wedge as shown in FIGS. 7 to 9. The wall module coupling surface 140 of the shape is formed, and the wall module coupling surface 140 increases the contact area of the connection part between the masonry wall panel modules 10 to waterproof the coupling part between the frames of each masonry wall panel module 10 , Improves windproof performance and strength.

In the masonry wall panel module 10 according to an embodiment of the present invention, the frame module 100 may be formed such that two or more rows of wedge-shaped concave grooves or wedge-shaped protrusions are arranged, and the frame module 100 is arranged in two or more rows. In the wedge-shaped concave groove or the wedge-shaped protrusion of the V-shaped wedge-shaped protrusion and a block 200 having a wedge-shaped concave groove are inserted, or as shown in FIG. 3C, the wedge-shaped protrusion and the wedge-shaped concave groove are in two rows. The block 200 in which the W-shaped wedge is formed can be inserted, and as shown in FIG. 4, the block 200 having a V-shaped or W-shaped wedge-shaped protrusion and a wedge-shaped concave groove is formed in both types. Are mixed, or any one type may be selected and mounted in the frame module 100 to be fitted.

Between the first and second horizontal frames 110 and 120 or the vertical frames 130 of the masonry wall panel module 10 according to an embodiment of the present invention, as shown in FIG. 5A, the inner central portion of each vertical frame 130 A horizontal intermediate frame 160 connecting to each other may be formed, or a vertical intermediate frame 160 connecting the inner central portions of the first and second horizontal frames 110 and 120 may be formed as shown in FIG. 5B, The intermediate frame 160 improves the rigidity of the frame module 100 to further improve the seismic performance of the constructed wall of the building.

In addition, the intermediate frame 160 may be formed with a chassis 161 to which a window or door is mounted as shown in FIG. 6, which is required to mount a window or door to a wall of a building through the chassis 161. The process and time can be greatly shortened.

The wall module coupling surface 140 formed at the connection between the masonry wall panel modules 10 according to an embodiment of the present invention includes a coupling groove 141 and a coupling pin 142 having a complementary shape as shown in FIG. 7 or 8. ) May be formed at least one each.

Each masonry wall panel module 10 fixed through the fastening member 146 through the fitting of the coupling groove 141 and the coupling pin 142 does not deviate from each other, so that the dimensional accuracy of the connection between the walls of the construction completed By improving it, the waterproof and windproof performance of the building is improved.

In addition, a sealing member 143 may be inserted into each wall module coupling surface 140, and waterproof and windproof performance of the connection between the masonry wall panel modules 10 through the sealing member 143 made of a water expansion index material, etc. Will improve more.

At this time, a protection cap for closing the fastening groove may be mounted in the fastening groove into which the fastening member 146 fixing each masonry wall panel module 10 is inserted, and the protection cap is along the fastening surface of the fastening member 146 It prevents the inflow of rainwater, etc., prevents the occurrence of corrosion of the fastening member 146 due to external environment exposure, and improves the aesthetics of the building by preventing the fastening member from being exposed in appearance.

On the wall module coupling surface 140 between the masonry wall panel modules 10 according to an embodiment of the present invention, one or more hooks 144 and hook grooves 145 having a complementary shape as shown in FIG. 10 may be formed. The hook 144 is made of an elastic material so that the hook 144 and the hook groove 145 are fitted together.

After connecting the wall module coupling surface 140 between the masonry wall panel modules 10 through the fitting coupling between the hook 144 and the hook groove 145, and before fixing through the fastening member 146, the masonry wall is temporarily coupled By preventing the separation between the panel modules 10, the wall module can be fixed more easily, and the hook 144 and the hook groove 145 are formed along the entire surface of the wall module coupling surface 140 In this case, in addition to the sealing member 143, the waterproof and windproof performance of the building is further improved.

In the masonry wall panel module 10 according to an embodiment of the present invention, a pipe 150 on which a water pipe, an electric wire, or a communication line is installed may be buried, or an insulation material or a heating wire may be buried, and more specifically shown in FIG. As described above, three or more wedge-shaped protrusions or concave grooves of the frame module 100 are formed in parallel, and the pipe 150, insulation material, or hot wire is embedded in the space formed between the blocks 200 built in the frame module 100 Can be.

In addition, some blocks 200 of the masonry wall panel module 10 may be built so that an electrical outlet is connected to the electric wire installed in the pipe 150, through which construction period and construction cost of installing water pipes, etc. It saves, improves the insulation performance of the constructed building, prevents the occurrence of condensation on the wall during cold weather, and changes the location of the block 200 when the block 200 is assembled, so that the installation location of the outlet can be easily adjusted.

In this case, a faucet or a communication terminal may be formed in the block 200 instead of an outlet. In this case, the faucet and the communication terminal are respectively connected to a water pipe or a communication line embedded in the masonry wall panel module 10.

A bracket 400 may be formed on the surface of the vertical frame 130 or block 200 of the masonry wall panel module 10 according to an embodiment of the present invention as shown in FIG. 12, and the bracket 400 includes a shelf Alternatively, the plate 410 of the table may be mounted, and the shelf or table can be easily installed on the interior wall of the building on which the construction has been completed through the bracket 400.

Hereinafter, a construction method using a masonry wall panel module composed of a block and a frame in which the wedge-shaped coupling part of the present invention is formed will be described as follows.

The construction method using the masonry wall panel module according to the present invention includes a frame module 100 cutting process (S10), a frame module first assembly step (S21), a block masonry step (S22), and a frame module second assembly step (S23). It consists of a masonry wall panel module manufacturing process (S20), a masonry wall panel module transportation process (S30), and a masonry wall panel module construction process (S40).

In the frame module 100 cutting process (S10), the first horizontal frame 110, the second horizontal frame 120, and the vertical frame 130 are cut according to the size of the wall of the building to be constructed.

Frame module 100 When the cutting process (S10) is completed, a frame module that connects the vertical frames 130 to both ends of the first horizontal frame 110 or the second horizontal frame 120 and fixes them with a fastening member 146 The first assembly step (S21) is performed. 6 shows a frame coupling surface formed in a complementary shape, respectively, with connection portions of the vertical frames 130 connected at both ends of the second horizontal frame 120 and both ends of the second horizontal frame 120.

A block masonry step of masonry by inserting a block 200 into a wedge-shaped protrusion or concave groove on the inner surface of the first horizontal frame 110 or the second horizontal frame 120 assembled in the frame module first assembling step (S21) (S22) ).

At this time, due to the geometric characteristics of the block 200 in which wedge-shaped protrusions and concave grooves are formed on the upper and lower surfaces, the block 200 can be stably stored only when the wedge-shaped concave groove is located at the bottom of the block masonry step (S22). It is preferable to connect the second horizontal frame 120 and the vertical frame 130 to each other in the first assembly step (S21) in order to prevent the occurrence of inconvenience of inserting the block 200 stored in the overturned.

When the masonry of the block 200 is completed, the first horizontal frame 110 or the second horizontal frame 120 is connected to the open end of the vertical frame 130, and the connection part of each frame is fixed with a frame fastening member. The frame module second assembly step (S23) is performed to complete the masonry wall panel module manufacturing process (S20) of manufacturing the masonry wall panel module 10.

In the block masonry step (S22), blocks 200 of different colors or materials are arranged in a certain order to form a pattern on the wall, thereby improving the aesthetics of the constructed building.

In the masonry wall panel module transport process (S30), the masonry wall panel module 10 manufactured in the masonry wall panel module manufacturing process (S20) is transported to the construction site, and the masonry wall panel module 10 is transported to the construction site. The masonry wall panel module construction process (S40) for installing the pre-built slabs (1) and pillars (2) of the building to construct the walls of the building is performed, and the masonry wall panel module 100 installed through the fixing member (11). ) Of the frame module 100 is firmly fixed to the slab (1) or the column (2).

At this time, a connection step (S41) of the masonry wall panel module 10 forming one large wall by connecting a plurality of masonry wall panel modules 10 may be added, and the connection step (S41) of the masonry wall panel module 10 ) In the case of forming a wall by connecting a plurality of masonry wall panel modules 100, the vertical frame 130 of the masonry wall panel module 10 connected to each other or the connection between the first and second horizontal frames 110 and 120 are fastened. It is fixed through the member 146.

Each of the masonry wall panel modules 10 connected to each other, the vertical frame 130 or the first and second horizontal frames 110 and 120 may be formed with a complementary staircase or wedge-shaped wall module coupling surface 140, The wall module coupling surface 140 increases the contact area between frames of the masonry wall panel module 10 to improve waterproof and windproof performance.

In addition, in the masonry wall panel module manufacturing process (S20), the frame module 100 may be formed by assembling a frame in which two or more rows of wedge-shaped concave grooves or wedge-shaped protrusions are arranged. In this case, in the block masonry step (S22) Wedge-shaped protrusions and wedge-shaped concave grooves are arranged in parallel to be built into the frame module 100, or wedge-shaped protrusions and wedge-shaped concave grooves are arranged in two rows to form a W-shaped wedge. The block 200 is formed in the frame module 100, and the V-shaped or W-shaped wedge-shaped protrusion and the block 200 having a wedge-shaped concave groove are both types mixed or one type is selected. It can be assembled and fitted into the frame module 100.

In the process of manufacturing the masonry wall panel module (S20), a process of connecting the vertical intermediate frame 160 to the inner central portion of the first horizontal frame 110 in the frame module first assembly step (S21) as shown in FIG. Alternatively, in the block masonry step (S22), a process of connecting the horizontal intermediate frame 160 to the inner center of each vertical frame 130 may be added, and the intermediate frame 160 and the first and second horizontal frames 110 and 120 Alternatively, the connecting portions between the two vertical frames 130 are fixed to each other by a fastening member 146, and the connecting portion between each frame including the vertical frame 130 has a complementary staircase or wedge-shaped wall module coupling surface 140 Can be formed.

At this time, a chassis 161 serving as a window frame or door frame may be formed in some intermediate frames 160 according to the design configuration of the building. After the masonry wall panel module construction process (S40) is completed, the chassis 161 Alternatively, the process of mounting the door (S50) is performed.

In addition, when a wedge-shaped protrusion is formed or a wedge-shaped concave groove is formed on both sides of the vertical frame 130 or the block 200 of the vertical intermediate frame 160 arranged to face each other, respectively, the block 200 and the frame Since the connection between the wedge-shaped projections or the connection between the wedge-shaped concave grooves occurs on the coupling surface of the block 200 and the frame may not be fixed, both sides are formed with a wedge-shaped projection or a wedge-shaped concave groove. By inserting the block 200, a wedge-shaped protrusion or a wedge-shaped concave groove of the block 200 connected to the frame can be switched.

In the masonry wall panel module construction process (S40), a complementary-shaped coupling groove 141 and a coupling pin 142 formed on the coupling surface 140 of the masonry wall panel module 10 coupled to each other are inserted and connected, and the wall module A process of inserting the sealing member 143 between the coupling surfaces 140 and mounting the protective cap in the fastening groove into which the fastening member 146 is inserted may be added.

Through the connection of the coupling groove 141 and the coupling pin 142, the connection portions between the masonry wall panel modules 10 are prevented from being displaced, thereby improving the dimensional accuracy of the connection portion between the walls of the constructed building.

In the masonry wall panel module construction process (S40), the joint between the frames to which each masonry wall panel module 10 is connected and the joint between the slabs (1) or pillars (2) of the building and the masonry wall panel module (10) are newly constructed. It is preferable to form a separation distance, and the expansion/contraction distance prevents excessive compressive or tensile force from occurring at the connection between the wall and the slab 1 when the frame contracts or expands due to seasonal temperature changes.

In order to prevent deterioration of the waterproof and windproof performance at the connection between the wall and the slab 1 due to the formation of the expansion and contraction distance, a process of forming a silicon caulking surface or the like at the connection between the wall and the slab 1 may be additionally performed. .

In addition, in the masonry wall panel module construction process (S40), a process of connecting the hook 144 formed on the wall module coupling surface 140 and the hook groove 145 to each other to form a complementary shape may be added, and the masonry wall Before the fixing through the fastening member 146 between the panel modules 10 is made, the hook 144 and the hook groove 145 are temporarily fixed to prevent separation between the temporarily coupled masonry wall panel modules 10. , The masonry wall panel module 10 with the fastening member 146 can be fixed to each other more easily.

At this time, by configuring the hook 144 and the hook groove 145 in a shape extending in the direction of the mating surface between the masonry wall panel module 10, the fitting of the coupling groove 141 and the coupling pin 142, the sealing member ( 143) Insertion and fastening member 146 In addition to the process of attaching the protective cap to the fastening groove, the waterproof and windproof performance of the connection between the wall of the building and the slab 1 can be further improved.

In addition, in the block masonry step (S22), a process of burying an insulation material or a heating wire in the masonry wall panel module 10, or burying a pipe 150 on which a water pipe, an electric wire, or a communication line is installed may be added. As shown in 11, by forming three or more wedge-shaped protrusions or concave grooves of the frame module 100, a block in which a V-shaped or W-shaped wedge-shaped protrusion and a wedge-shaped concave groove are formed inside the frame module 100 (200) may form a space that is not masonry, and a pipe 150, an insulation material, or a heating wire may be embedded in this space.

An electrical outlet, a communication terminal, or a faucet may be connected to the pipe 150, and an electrical outlet, a communication terminal, or a faucet is embedded in some blocks 200 of the masonry wall panel module 10 to connect the wires in the pipe 150, etc. In this case, in the block masonry step (S22) or during the remodeling process after completion of the building, the location of the block 200 containing an electric outlet or the like can be changed to easily change the location of the electric outlet.

When it is necessary to divide and form a building such as an office or restaurant into a plurality of indoor spaces, a process (S60) of installing the partition module 300 may be added.

The partition module 300 forms a partition module unit through a plurality of blocks 200 arranged to form a triangular star or cross-sectional shape by adhering side wedge-shaped protrusion surfaces to each other, as shown in FIGS. 13 to 16 And, each partition module unit is stacked to the designed partition height to form the partition module 300, or a V-shaped or W-shaped wedge-shaped protrusion and wedge on each wedge surface of the partition frame 310 having a wedge-shaped coupling portion formed. It can be formed by mounting and stacking the block 200 in which the type concave groove is formed.

The strength of the constructed partition module 300 may be improved by bonding the bonding surfaces between the partition module unit and each block 200 or partition frame 310 constituting the partition module 300 to each other.

At this time, after completion of the process of installing the partition module 300 (S60), it is perpendicular to the V-shaped or W-shaped wedge-shaped protrusion and the wedge-shaped recess formed on the outermost side of the stacked block 200 of the partition module 300. A process of installing the frame 130 and installing the fixture 320 along the height direction of the partition module 300 on the side surface of the connection portion between the stacked blocks 200 of the partition module 300 may be added. The frame 130 prevents the stacked blocks 200 of the partition module 300 from shifting from each other, and the fixture 320 has the dimensional accuracy of the space divided by the partition module 300 as the angle of the connection portion of the formed partition is changed Is prevented from falling

In addition, the vertical frame 130 and the fixture 320 installed in the partition module 300 prevent separation between the stacked blocks 200 or the partition module units when a strong external force is applied due to an earthquake, etc. And stiffness can be further improved.

As shown in FIG. 12, a bracket 400 on which a plate 410 of a shelf or table is mounted may be formed on the surface of the vertical frame 130 or block 200 of the masonry wall panel module 10, and the masonry wall After the panel module 10 construction process (S40) is completed, the plate 410 of the shelf or table is mounted on the bracket 400, and then fixed with a fastening member 146 so that the shelf or table can be easily installed.

In addition, as shown in FIGS. 13 to 15, the bracket 400 on which the plate 410 of the shelf or table is mounted is formed on the side surface of the vertical frame 130 or the fixture 320 of the partition module 300, thereby Through 400, a shelf or a table can be easily installed on the side of the partition module 300, and when a table needs to be installed in each divided space such as an office or a cafe, the construction cost and time required to install the table can be greatly increased. Can be reduced.

In particular, the partition module 300 according to the present invention forms a partition wall surface by masonrying blocks 200 having a high density and strength, so that there is no external impact on the partition wall surface compared to a partition formed by connecting panels according to the conventional method. When noise is transmitted, it is possible to improve the quietness of an office or a cafe by preventing amplification of the noise while generating an echo.

Although the embodiments of the present invention have been described with reference to the above, those skilled in the art to which the present invention pertains will understand that the present invention can be implemented in other specific forms without changing the technical spirit or essential features.

Therefore, the embodiments described above are to be understood as illustrative and non-limiting in all respects, and the scope of the present invention described in the detailed description is indicated by the claims to be described later, and the meaning of the claims and It should be construed that all changes or modifications derived from the scope and equivalent concepts are included in the scope of the present invention.

1: slab 2: pillar
10: masonry wall panel module 11: fixing member
100: frame module 110: first horizontal frame
120: second horizontal frame 130: vertical frame
140: wall module coupling surface 141: coupling groove
142: coupling pin 143: sealing member
144: hook 145: hook groove
146: fastening member 150: piping
160: middle frame 161: chassis
200: block 300: partition module
310: partition frame 320: fixture
400: bracket 410: plate

Claims (16)

delete delete delete The first horizontal frame 110 in which a V-shaped or W-shaped wedge-shaped concave groove is formed over the entire lower surface according to the size of the wall of the building in which the slabs (1) and columns (2) are pre-installed, and the upper surface Cutting the second horizontal frame 120 having a V-shaped or W-shaped wedge-shaped protrusion over and a vertical frame 130 having a V-shaped or W-shaped wedge-shaped protrusion or wedge-shaped concave groove over the entire inner surface The frame module 100 cutting process (S10);
A vertical frame connected to both ends of the first horizontal frame 110 or the second horizontal frame 120 and the first horizontal frame 110 or the second horizontal frame 120 each having a frame engaging surface of a complementary shape A frame module first assembly step (S21) of fixing 130 with a frame fastening member,
Block masonry step of masonry by inserting a block 200 having a V-shaped or W-shaped wedge-shaped protrusion and a wedge-shaped concave groove over the upper surface and the entire front of one side and the lower surface and the other side of the connected frame (S22) ), and
Consists of a second assembly step (S23) of a frame module in which the first horizontal frame 110 or the second horizontal frame 120 is connected to the open end of the vertical frame 130 and then fixed with a frame fastening member. Masonry wall panel module manufacturing process to form the wall surface (1) masonry wall panel module 10 (S20);
The masonry wall panel module transport process (S30) for transporting the manufactured masonry wall panel module 10 to the construction site;
The masonry wall panel module construction process (S40) of forming a wall by fixing the frame module 100 of the masonry wall panel module 10 to the slab 1 or column 2 of the building (S40):
In the masonry wall panel module construction process (S40), the vertical frame 130 or the first and second horizontal frames 110 and 120 of the frame module 100 have a complementary staircase or wedge-shaped wall module coupling surface 140 ) Is formed to connect a plurality of wall panel modules 10 to each other, and then the connection between the frame modules 100 is fixed with a fastening member 146 to form a wall, which is a step of connecting the masonry wall panel module 10 (S41). A construction method using a masonry wall panel module consisting of a block and a frame in which a wedge-shaped coupling part is formed, characterized in that it contains. delete The method of claim 4,
The frame module 100 is formed such that two or more rows of wedge-shaped concave grooves or wedge-shaped protrusions are arranged,
In the block masonry step (S22), the block 200 in which the V-shaped wedge-shaped protrusion and the wedge-shaped concave groove is formed is inserted into the frame module 100,
The wedge-shaped protrusion and the wedge-shaped concave groove are arranged in two rows so that the block 200 having a W-shaped wedge is inserted into the frame module 100,
The wedge-shaped protrusion and the wedge-shaped concave groove formed in a V-shaped or W-shaped block 200 are wedge-shaped, characterized in that both types are mixed or one type is selected to be masonry and fitted into the frame module 100 A construction method using a masonry wall panel module composed of a block and a frame with a coupling part formed. The method of claim 4,
In the manufacturing process (S20) of the masonry wall panel module (S20), one end of the vertical intermediate frame 160 is connected to the inner center of the first horizontal frame 110 in the frame module first assembly step (S21), and the frame module In the second assembly step (S23), a process of connecting the other end of the vertical intermediate frame 160 to the inner central portion of the second horizontal frame 120 is added, or
Alternatively, in the block masonry step (S22), a process of connecting the horizontal intermediate frame 160 to the inner central portion of each vertical frame 130 is added. Building construction method using. The method of claim 7,
A chassis 161 serving as a window frame or door frame is formed in the vertical or horizontal intermediate frame 160, and after the masonry wall panel module construction process (S40) is completed, the process of mounting a window or door to the chassis 161 ( S50) is a building construction method using a masonry wall panel module consisting of a block and a frame formed with a wedge-shaped coupling portion, characterized in that the addition. The method of claim 4,
At least one coupling groove 141 and a coupling pin 142 having a complementary shape are formed on the wall module coupling surface 140 to be coupled to each other, and a coupling groove 141 in the construction process (S40) of the masonry wall panel module 10 ) And the coupling pin 142 to each other, inserting the sealing member 143 between the wall module coupling surface 140, and attaching the protective cap to the coupling groove into which the coupling member is inserted. A construction method using a masonry wall panel module consisting of a block and a frame in which a wedge-shaped coupling part is formed. The method of claim 4,
One or more hooks 144 and hook grooves 145 are each formed to form a complementary shape between the wall module coupling surfaces 140 that are coupled to each other, and the masonry walls connected to each other in the construction process (S40) of the masonry wall panel module 10 A masonry wall panel consisting of a block and a frame with a wedge-shaped coupling portion, characterized in that a process of temporarily fixing by inserting the hook 144 and the hook groove 145 before fixing through the fastening member between the panel modules 10 is added. Building construction method using modules. The method of claim 6,
Building construction method using a masonry wall panel module consisting of a block and a frame with a wedge-shaped coupling portion, characterized in that the process of burying an insulation material or a heating wire inside the masonry wall panel module 10 in the block masonry step (S22). The method of claim 6,
In the block masonry step (S22), the process of burying the pipe 150 in which water pipes, wires, or communication lines are installed inside the masonry wall panel module 10, and some blocks 200 of the masonry wall panel module 10 A construction method using a masonry wall panel module consisting of a block and a frame with a wedge-shaped coupling part, characterized in that a process of connecting the electrical outlet to the electric wire in the pipe 150 is added. The method of claim 4,
After the masonry wall panel module 10 construction process (S40), a process (S60) of installing the partition module 300 serving as a partition that divides the indoor space of the constructed building is added,
In the process of installing the partition module 300 (S60), the side wedge-shaped protrusion surfaces between the plurality of blocks 200 are bonded to each other to be connected, or
A wedge-shaped concave groove or a wedge-shaped protrusion between a plurality of blocks 200 having a V-shaped or W-shaped wedge-shaped protrusion and a wedge-shaped concave groove formed on each wedge surface of the partition frame 310 having a wedge-shaped coupling part is formed. Bonding and connecting to form a partition module unit,
A construction method using a masonry wall panel module consisting of a block and a frame with a wedge-shaped coupling part, characterized in that each partition module unit is stacked to a designed partition height to form the partition module 300. The method of claim 13,
After the process of installing the partition module 300 (S60) is completed, a process of installing a vertical frame 130 and a fastener 320 having a wedge-shaped corner is added to the partition module 300,
The vertical frame 130 is installed in a V-shaped or W-shaped wedge-shaped protrusion and a wedge-shaped concave groove at the outermost of the stacked block 200 of the partition module 300,
The fixture 320 is a masonry wall composed of a block and a frame in which a wedge-shaped coupling portion is formed, characterized in that it is installed along the height direction of the partition module 300 on the side surface of the connection portion between the stacked blocks 200 of the partition module 300 Construction method using panel modules. The method of claim 4,
A bracket 400 on which a plate 410 of a shelf or a table is mounted is formed on the surface of the vertical frame 130 or block 200 of the masonry wall panel module 10,
In the masonry wall panel module 10 construction process (S40), after mounting the plate 410 of the shelf or the table on the bracket 400, a process of fixing the bracket 400 and the plate 410 with a fastening member is added. A construction method using a masonry wall panel module consisting of a block and a frame in which a wedge-shaped coupling part is formed. The method of claim 14,
A bracket 400 on which the plate 410 of the shelf or table is mounted is formed on the side surface of the vertical frame 130 or the fixture 320 of the partition module 300,
In the process of installing the partition module 300 (S60), after mounting the plate 410 of the shelf or the table on the bracket 400, a process of fixing the bracket 400 and the plate 410 with a fastening member is added. A construction method using a masonry wall panel module consisting of a block and a frame in which a wedge-shaped coupling part is formed.

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