KR102712102B1 - S - MFS(Suspended - Module For Shaft) method of objects standing through floors - Google Patents

Abstract

The present invention relates to a stationary shaft modularization method of an interlayer penetrating granular material installed in a duct shaft zone, and comprises a frame frame installed on a duct shaft zone, a slab frame fitted into the duct shaft zone and integrated with one layer of slab, and an insulating frame matching the bottom of one layer, thereby enabling modularization of GCS CT (Gas Chemical Supply Center) pipes, HVAC duct pipes, and Electric Trays installed in a DS Zone.
According to the static shaft modularization method of the interlayer penetrating granular material of the present invention, the interlayer penetrating granular material to be installed in the duct shaft zone (DS Zone) is modularized and manufactured in a factory, thereby shortening the construction period by conducting earthquake-resistance, shielding, and leak tests of the interlayer penetrating part in advance.

Description

Suspended-Module For Shaft (S-MFS) method of objects standing through floors

The present invention relates to a stationary shaft modularization method for interlayer penetrating granular materials, and more particularly, to a stationary shaft modularization method for interlayer penetrating granular materials, which modularizes a part of an interlayer penetrating granular material to be installed in a duct shaft zone (DS Zone) and manufactures it in a factory, thereby shortening the construction period by conducting earthquake resistance, fire resistance, shielding, and leak tests on the interlayer penetrating portion in advance, and which connects an interlayer penetrating granular material with a non-penetrating granular material to make it one.

In general, pipes for facilities such as HVAC (Heating, Ventilation, and Air Conditioning) often penetrate between floors of a building. In this case, fireproofing material must be installed to block heat transfer through the pipe in the event of a fire and prevent the spread of fire. First, the concrete at the penetration site is cut to form a penetration hole or the slab is poured excluding the penetration hole. The penetration hole should be larger than the pipe. Then, the pipe is inserted into the penetration hole and secured using lugs and buffer springs so that the pipe is firmly fixed to the penetration hole. Next, fireproofing material is filled in the empty space between the pipe and the penetration hole. The fireproofing material is a flame retardant material that blocks heat transfer through the pipe in the event of a fire and prevents the spread of fire. Then, fireproofing sealant is applied to the surface of the fireproofing material. The fireproofing sealant strengthens the sealing of the fireproofing material and prevents movement of the pipe.

For general buildings or apartments that do not have many inter-floor penetrating particles, construction is not complicated. However, the DS Zone (Duct Shaft Zone), which acts as the aortic tunnel of a semiconductor manufacturing plant, requires the effective control of air flow between the process room and the clean room, so construction is complicated because devices such as dampers, filters, and ventilators are installed. In particular, Semiconductor Equipment and Materials International (SEMI), which establishes international standards to improve process safety and quality in semiconductor manufacturing plants, presents the following requirements for the DS Zone of a semiconductor manufacturing plant. The DS Zone must be installed with GCS CT (Gas Chemical Supply Center) pipes, HVAC duct pipes, and electric trays, must be able to prevent leakage, must be designed with a sealed structure, and must undergo regular leak tests.

However, in order to satisfy SEMI S3000 (standard for duct shaft zones in semiconductor manufacturing plants) at the construction site of a new semiconductor manufacturing plant, high-quality materials and equipment must be used, construction requires a lot of man-hours, and sufficient time is needed for the design and construction of the duct shaft zone, which may cause a delay in the plant construction schedule. Since SEMI S3000 strictly regulates the airtightness and leakage of the duct shaft zone, the interlayer penetration section must be thoroughly sealed. Therefore, collaboration between engineers with professional knowledge and experience in safety and quality and the company constructing the interlayer penetration section is necessary, and sufficient construction time must be secured and thorough quality control must be performed, so there was a limit to shortening the construction period.

In addition, since the companies that construct the granular penetrations for piping, firefighting, gas, and air conditioning are different, there are problems such as interference with the construction process with other companies when determining the construction order or making modifications after construction, and the installation location of the reinforcing material used when installing the granular penetrations in the duct shaft zone is different for each company, which is inconsistent, and the interference between the firewall and the reinforcing material around the duct shaft zone must be considered, resulting in a lot of trial and error.

<Prior art research literature>

Document 1: Patent Publication No. 10-1209590

Document 2: Patent Registration No. 10-1971500

Document 3: Patent Publication No. 1923629

The present invention has been made to solve the above-described problems, and by modularizing interlayer penetrating granular materials to be installed in the DS Zone of a semiconductor manufacturing plant and manufacturing them in a factory, earthquake resistance, fire resistance, shielding, and leakage tests can be performed in advance, thereby shortening the construction period. In addition, the interlayer penetrating granular material section required by SWMI S3000 can be modularized to present a construction standard, and a stationary shaft modularization method of interlayer penetrating granular materials that can be applied to general multi-use buildings is provided.

The present invention provides a method for forming a stationary shaft modular structure of an interlayer penetrating granular body to achieve the above object, the method comprising: forming a frame frame including at least one penetrating granular body protruding upward and downward from a floor through a duct shaft zone and being placed and fixed on a floor beam or slab of the floor surrounding the duct shaft zone; forming a slab frame including at least one penetrating hole through which the penetrating granular body passes, the step of connecting the frame frame and the slab frame, and then pouring concrete into the slab frame except for the penetrating hole to form a plurality of shaft modules installed in each floor; the step of inserting the shaft module into the duct shaft zone of the one floor, pouring concrete into the gap between the duct shaft zone and the slab frame, and allowing it to cure; and the step of inserting and curing each shaft module in each duct shaft zone of each floor, and welding a non-penetrating granular body between the penetrating granular bodies protruding upward and downward from each floor to connect them as one.

A step for forming a frame frame body including at least one through-granular body protruding upward and downward from a floor through a duct shaft zone and being placed and fixed on a floor beam or slab of the floor surrounding the duct shaft zone; A step for forming a slab frame body fitted to the duct shaft zone and including at least one through-hole through which the through-granular body passes; A step for connecting the frame frame body and the slab frame body and then pouring concrete into the slab frame body except for the through-holes to form a plurality of shaft modules installed for each floor; A step for inserting one shaft module into the duct shaft zone of the one floor and pouring concrete into the gap between the duct shaft zone and the slab frame body to allow curing; And it may include a step of inserting a non-penetrating granular material into a duct shaft zone of another layer directly above one of the layers so that a lower end is connected to an upper end of the penetrating granular material by welding, then inserting another shaft module into the duct shaft zone of the other layer and curing it, and repeating the process of welding the penetrating granular material at the lower end to the upper end of the non-penetrating granular material for each layer.

The above frame body includes a plurality of earthquake-resistant springs that support a plurality of lugs formed radially on the outer surface of the through-hole, and a refractory filler may be filled between the through-hole and the through-hole.

An insulating frame body may be included that blocks the open lower portion of the slab frame body except for the above-mentioned penetration hole to support the concrete while it cures, and is connected to the frame frame body through a connecting hole penetrating the slab frame body.

The above shaft module may be configured symmetrically as a pair of frame frames and slab frames depending on the size of the duct shaft zone, or may be configured as a single body, and when configured separately, the opposing surfaces of the frame frames may be connected by bolts at the construction site.

According to the static shaft modularization method of the interlayer penetrating granular material of the present invention as described above, by inspecting the sealing and leakage in advance during the process of modularizing and manufacturing the GCS CT (Gas Chemical Supply Center) pipes, electric trays, and HVAC duct pipes installed in the DS Zone, the sealing and leakage tests required by SWMI S3000 can be passed, thereby shortening the construction period.

In addition, when installing a vertical penetration in the DS Zone, there is no need for high-altitude work to attach the reinforcing material to the slab or floor beam, which has the effect of preventing safety accidents due to falls.

Figure 1 is a conceptual diagram of an interlayer penetrating shaft module of one embodiment of the present invention.
Figure 2 is a conceptual diagram showing the installation process of an interlayer penetrating shaft module of one embodiment of the present invention.
Figure 3 is a construction status diagram of a stationary shaft modularization method for an interlayer penetrating granular material according to one embodiment of the present invention.
Figure 4 is a conceptual diagram of an interlayer penetrating shaft module according to another embodiment of the present invention.
Figure 5 is a perspective view of the frame body of the interlayer penetrating shaft module of one embodiment of the present invention.
Figure 6 is a perspective view of a slab frame of an interlayer penetrating shaft module of one embodiment of the present invention.

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

Hereinafter, in Figures 1 to 6, the X-axis coordinate is referred to as the ‘left-right direction’, the Y-axis coordinate is referred to as the ‘front-back direction’, and the Z-axis coordinate is referred to as the ‘up-down direction’.

The penetrating granular material (400) used in the interlayer penetrating shaft module in the present invention may be a GCS CT (Gas Chemical Supply Center) pipe, an Electric Tray, and an HVAC duct pipe installed in a DS Zone of a semiconductor manufacturing plant, and may also be an HVAC duct pipe of a general building.

As illustrated in (a) of FIG. 1, a stationary shaft modularization method of an interlayer penetrating granular material according to one embodiment of the present invention may include a step of forming a pair of mutually symmetrical frame frames (100), a step of forming a pair of mutually symmetrical slab frames (200), and a step of forming a pair of mutually symmetrical insulating frames (300).

The step of forming the above pair of frame frames (100) is a step of vertically erecting a portion of a penetrating granular material (400) penetrating the upper and lower sides of a duct shaft zone (500) of one layer. It is convenient for transport and manufacturing if the penetrating granular material (400) has a length that protrudes about 1 m from the upper and lower sides of the duct shaft zone (500) of one layer.

At this stage, each frame body (100) may include an "H" beam and a "ㄷ" shaped steel welded in a lattice shape, and an earthquake-resistant spring (402) that supports a lug (401) formed on an outer periphery of a penetrating member (400). The penetrating member (400) may be vertically erected on each frame body (100) when the lug (401) is placed on and fixed to the earthquake-resistant spring (402). In addition, each frame body (100) may include a plurality of upper and lower frames (103) that function as legs and protrude beyond a slab floor of one layer. In addition, each upper and lower frame (103) is fixed to a floor beam or slab with an anchor bolt at a lower end outside a duct shaft zone (500).

As illustrated in FIG. 5, a frame body (100) of one embodiment of the present invention is configured to include a pair of left and right frames (101) separated from each other in which an H-beam is formed long in the left and right direction, a plurality of front and rear frames (102) in which an H-beam is welded in the front and rear direction between each of the left and right frames (101), and a plurality of upper and lower frames (103) in which an H-beam is welded in the upper and lower direction to the lower portions of each of the left and right frames (101).

Each left and right frame (101) and each upper and lower frame (103) is formed larger than a duct shaft zone (500) penetrating between floors, and the lower part of each upper and lower frame (103) is configured to include a bracket (104) that is connected to a floor beam or an inter-floor slab with an anchor bolt while avoiding the duct shaft zone (500).

A pair of left and right jig frames (105) provided so as to be spaced apart from each other in the left and right directions above each pair of front and rear frames (102) are configured to include a support member (107) at both ends that is fitted into a groove of an H-beam open to the upper portion of the front and rear frames (102).

A pair of front and rear jig frames (106) provided apart from each other on the upper surface of each left and right jig frame (105) are configured to include a number of spacing adjustment grooves (108) spaced at equal intervals so as to fit into the vertical surface of the “ㄷ” shaped steel that is open to the upper portion of the left and right jig frames (105).

Each front and rear jig frame (106) is configured to include a fastening hole (109) into which a fastening hole (110) is inserted and bolted so that the distance between them is fixed through the fastening hole (110).

The penetrating granular material (400) protruding about 1 m above and below each layer through the above duct shaft zone (500) is configured to include a number of lugs (401) that are placed and fixed on earthquake-resistant springs (402) provided on each front and rear jig frame (106) and left and right jig frames (105).

Meanwhile, the step of forming each slab frame (200) may include a form (201) that is open at the top and bottom for pouring concrete. The four side walls of the form (201) may be composed of a frame and a blocking bar manufactured by the tamaga method of Patent No. 1127298.

In addition, the inside of the formwork (201) may include a through hole (202) through which a penetrating particle (400) passes, and a number of reinforcing bars or angles may be built in to increase durability. Here, the outer circumference of the formwork (201) on all sides may include a connecting reinforcing bar (212) corresponding to a connecting reinforcing bar (501) protruding into the floor beam or slab of the duct shaft zone (500).

As illustrated in FIG. 6, a slab frame (200) of an embodiment of the present invention is configured to include left and right angles (203) and front and rear angles (204) that are arranged in a grid pattern so as to intersect in the left and right directions and front and rear directions inside. The left and right angles (203) are made of “L” shaped steel, and are configured to include a plurality of insertion grooves (206) and reinforcing bar holes (207) at equal intervals on the vertical surface and the horizontal surface, respectively. The front and rear angles (204) are configured to include insertion grooves (208) that enter the insertion grooves (206) on the vertical surface downward, and to include reinforcing bar holes (209) corresponding to the reinforcing bar holes (207) on the horizontal surface, and reinforcing bars (210) are inserted into and combined in each reinforcing bar hole (207)(209).

The left and right angles (203) and the front and rear angles (204) are configured to include a through hole (202) in a position where a through-hole (400) is inserted. The through hole (202) is configured to include a flange (202a) whose upper end penetrates the upper part of the slab frame (200) and whose lower end penetrates the lower part of the insulating frame (300), and whose outer surface includes a number of protrusions embedded in concrete. The left and right angles (203) and the front and rear angles (204) corresponding to the through hole (202) are partially removed through oxygen cutting, and the outer surface of the through hole (202) is fixed by welding to the sides of the remaining left and right angles (203) and the front and rear angles (204), or can be fixed in close contact in a surface-contact manner through a latch connected to the angles (203) (204).

The through hole (202) is formed larger than the through hole (400), and a refractory filler (403) is filled between the through hole (202) and the through hole (400). The mold (201) is configured to include a support angle (205) having insertion grooves (211) formed at equal intervals on both sides of the inner surface in the left and right directions, into which both ends of the left and right angles (203) are inserted.

As illustrated in FIG. 1, an insulating frame (300) of one embodiment of the present invention is configured to include a bottom plate (301) that is attached to an inner surface of the duct shaft zone (500) and has a wing portion (305) that protrudes outward at the top and is placed under the connecting reinforcing bar (212)(501) and is fastened to a floor beam or slab with an anchor bolt (305a).

And, the interior is configured to include a number of “L”-shaped reinforcing angles (302) at equal intervals in the front-back direction, and a compressed styrofoam-type insulation material (303) is included between each reinforcing angle (302).

Each reinforcing angle (302) and each left and right frame (101) are connected through a number of connecting holes (304) penetrating the slab frame (200), and the slab frame (200) is completed by pouring concrete covering the insulating frame (300). Each connecting hole (304) is composed of a wire rope, and both ends are bent into a ring shape and can be fixed to the corresponding side through bolts and nuts.

The modular construction method of one embodiment of the present invention can be made as a single body or separated into two parts depending on the size of the duct shaft zone (500).

In the case of a separately configured method, the corresponding frame frame (100), slab frame (200) and insulation frame (300) are configured as a pair, and the opposing front and rear frames (102) of each frame frame (100) are bolted together, and each slab frame (200) is configured with connecting reinforcing bars (212) included in all directions of the outer circumference.

As illustrated in (b) of FIG. 1, the stationary shaft modularization method of the interlayer penetrating granular material of one embodiment of the present invention may include a step of assembling a pair of separate frame frames (100), a slab frame (200), and an insulating frame (300) to create a pair of shaft modules (M).

Here, the frame frame (100), the slab frame (200), and the insulating frame (300) are sequentially laminated, and the lower part of the through-hole (400) can be fitted into the through-hole (202). In addition, the insulating frame (300) can be hung on the frame frame (100) through a connecting hole (304) penetrating the slab frame (200), so that the frame frame (100), the slab frame (200), and the insulating frame (300) are connected as one.

Next, concrete is poured into each mold (201) and cured, and a refractory filler (403) is filled between the through hole (202) and the through-hole granular material (400), and a refractory sealant is applied to the upper and lower parts of the refractory filler (403) exposed to the outside and around the through-hole granular material (400), and then wrapped with a flame retardant to complete a pair of shaft modules (M).

Figures 2 (a) and (b) illustrate the steps of transporting a pair of shaft modules (M) to a new construction site and performing construction on the corresponding floor (F).

In this step, each shaft module (M) is installed in the duct shaft zone (500) using a crane. At this time, each shaft module (M) is placed with the lower end of the upper and lower frames (103) of the frame body (100) on the floor beam or slab of the corresponding floor (F), and the corresponding frame bodies (100) can be connected as one by having their opposing surfaces bolted together. Thereafter, the bracket (104) formed at the lower end of the upper and lower frames (103) can be fixed to the floor beam or slab with an anchor bolt so that the two shaft modules (M) can be connected as one.

Here, a pair of slab frames (200) and a pair of insulating frames (300) are fitted into a duct shaft zone (500), and connecting reinforcing bars (212) on opposite sides of a pair of slab frames (200) are arranged in an intersecting manner, and connecting reinforcing bars (212) on the remaining three sides can be arranged in proximity to the floor beam of the duct shaft zone (500) or the connecting reinforcing bars (501) of the slab.

In addition, a pair of insulating frames (300) can act as a concrete form that blocks the open bottom of the connecting reinforcing bars (212) placed on the opposite surfaces of a pair of slab frames (200) by being in close contact with each other on the opposite surfaces, and the remaining three surfaces can be in close contact with the inner surface of the duct shaft zone (500) by being in close contact with each other on the three surfaces of each slab frame (200) and the bottom of the connecting reinforcing bars (501) of the floor beam or slab of the duct shaft zone (500).

Next, by pouring concrete between the duct shaft zone (500) and the slab frame (200) using the tamaga method and allowing it to cure while the connecting reinforcing bars (212)(501) on both sides are embedded, the slab frame (200) and the floor beam or slab of the corresponding floor (F) can be connected as one.

The slab frame (200) is configured with a formwork (201) in a tamaga manner, and the edge of the duct shaft zone (500) is also formed in a tamaga manner. Therefore, when concrete is filled between them, they are connected as one by the tamaga method.

As illustrated in FIG. 3, the stationary shaft modularization method of the interlayer penetrating granular material of one embodiment of the present invention may include a step of installing a shaft module (M) in a duct shaft zone (500) of each layer (F).

Here, the penetrating granular material (400) of the shaft module (M) protruding from the upper and lower parts of each layer (F) can be connected to the non-penetrating granular material (P). At this time, the non-penetrating granular material (P) and each penetrating granular material (400) can be connected as one by welding their opposing surfaces. In general buildings that do not require high airtightness, flanges can be installed at the upper and lower parts of the penetrating granular material (400), and flanges can also be installed at the upper and lower parts of the non-penetrating granular material (P), and then packing can be inserted between these flanges and fastened with bolts to connect them as one.

As illustrated in FIG. 4, the stationary shaft modularization method of the interlayer penetrating granular material of another embodiment of the present invention is constructed in a duct shaft zone (500) using the same method as one embodiment of the present invention, except that the frame frame (100), the slab frame (200), and the insulation frame (300) are each made as one unit.

Here, in one embodiment of the present invention, the length of one side of the floor beam constituting the duct shaft zone (500) is 10M or longer and the gap between the floor beams is 4M or longer, which corresponds to a case where the shaft module (M) is manufactured as a single body and therefore has a large volume, making transport and construction difficult. In another embodiment of the present invention, the length of one side of the floor beam constituting the duct shaft zone (500) is formed to be 4M or shorter, making production and transport easy.

The stationary shaft modular construction method of the interlayer penetrating granular material according to the present invention, which is constructed in the above-described steps, is not affected by the construction schedule of the construction site because the shaft module (M) is manufactured in advance at the factory. Therefore, the earthquake resistance, fire resistance, and sealing performance of the interlayer penetrating portion can be reviewed and approved in advance, and the penetrating granular material (400) of the shaft module (M) installed on each floor can be connected as one by welding the upper and lower parts with non-penetrating granular materials of the same size, so that the construction period can be quickly shortened.

The construction process for each step of the stationary shaft modularization method for interlayer penetrating granular materials according to the present invention is as follows.

First, a through hole (202) is installed in the slab frame (200) to allow a through-hole (400) to pass through. Since the left and right angles (203) and the front and rear angles (204) are spaced apart in a grid shape and the fitting grooves (206)(208) are combined, the grid-shaped spacing can be used as XY orthogonal coordinates to easily determine the position where the through hole (202) is to be placed. The left and right angles (203) and the front and rear angles (204) at the position where the through hole (202) is to be placed are partially oxygen-cut, and the through hole (202) can be fixed by welding to the cut side or can be tightly attached using a latch.

Likewise, the insulating frame (300) is cut with a reinforcing angle (302) and a portion of the insulating material (303) so that the through hole (202) is fitted. Next, a plurality of lugs (401) are welded radially to the outer periphery of the middle point of the through hole (400). Preferably, they are formed in four or eight directions, and an earthquake-resistant spring (402) is bolted to the upper surface of the front and rear jig frames (106) and the left and right jig frames (105) at each location where the lugs (401) are to be placed.

In addition, a pair of left and right jig frames (105) are placed between a pair of front and rear frames (102) through a support member (107) so as to be close to the outer periphery of the through-hole particle (400), and a pair of front and rear jig frames (106) are placed on the left and right jig frames (105) through a spacing adjustment groove (108). Since the spacing adjustment grooves (108) are formed in the front and rear jig frames (106) so as to correspond to the through-hole particle (400) formed in various sizes, by using these spacing adjustment grooves (108), the front and rear jig frames (106) and the left and right jig frames (105) can be arranged to intersect at right angles so as to be close to the outer periphery of the through-hole particle (400).

Next, the left and right jig frames (105) and front and rear jig frames (106) that are intersected in a grid pattern are placed at the center of the through hole (202), so that the left and right jig frames (105) move in a straight line along the front and rear frames (102) through the support member (107), and the front and rear jig frames (106) move in a straight line along the left and right jig frames (105) through the spacing adjustment groove (108), thereby allowing the X-axis and Y-axis orthogonal coordinates to be finely adjusted.

Likewise, the penetrating particle (400) is inserted between the left and right jig frames (105) and the front and rear jig frames (106) that are intersected in a grid pattern, and is inserted into the penetrating hole (202), and then the lug (401) is coupled to the corresponding earthquake-resistant spring (402), and by finely adjusting the left and right jig frames (105) and the front and rear jig frames (106), the penetrating particle (400) and the penetrating hole (202) can be concentrically aligned.

Afterwards, a refractory filler (403) is filled between the penetration hole (202) and the penetration granular material (400), the insulating frame (300) is filled with an insulating material (303) between each reinforcing angle (302), the reinforcing angle (302) and the left and right frames (101) are connected by a connecting hole (304), and then concrete is filled inside the formwork (201) and cured to create one shaft module (M).

In the above, the shaft module (M) can be manufactured using only the frame frame (100) and the slab frame (200) without using the insulating frame (300). When manufacturing the shaft module (M) in a factory, the open bottom of the slab frame (200) is blocked with concrete foam to prevent the concrete from leaking out of the form (201), and the front and rear angles (204) or left and right angles (203) inside the form (201) and the left and right frames (101) of the frame frame (100) are connected to each other with a connecting hole to form an integrated structure, and then a step of pouring concrete may be included.

As illustrated in FIG. 3, according to the modular construction method of one embodiment of the present invention, by inserting a shaft module (M) into a duct shaft zone (500) of a certain floor (F) and pouring concrete between the slab frame (200) and the duct shaft zone (500) and curing it, the certain floor (F) and the slab frame (200) can be integrated through connecting reinforcing bars (212) (501).

Next, a non-penetrating granular material (P) is fitted into a duct shaft zone (500) on another layer (F) above, and the upper end of the penetrating granular material (400) vertically erected on a shaft module (M) of one layer (F) and the lower end of the non-penetrating granular material (P) are connected by welding. After that, a shaft module (M) is installed on a duct shaft zone (500) of another layer (F), and then the lower end of the penetrating granular material (400) of the other layer (F) and the upper end of the non-penetrating granular material (P) are connected by welding to form one. By repeating this process, the penetrating granular material (400) and the non-penetrating granular material (P) of the shaft module (M) can be continuously connected on each layer (F).

Alternatively, a shaft module (M) may be installed in a duct shaft zone (500) for each floor (F), and then a non-penetrating member (P) may be welded to the top and bottom of a penetrating member (400) protruding from the top and bottom of the corresponding floor (F) to connect them continuously.

Although the above description has presented and described preferred embodiments of the present invention, the present invention is not necessarily limited thereto, and those skilled in the art to which the present invention pertains will easily understand that various substitutions, modifications, and changes can be made within the scope that does not depart from the technical spirit of the present invention.

100: Frame frame 101: Left and right frames
102: Front and rear frames 103: Top and bottom frames
104: Bracket 105: Left and right jig frames
106: Front and rear jig frame 200: Slab frame
201 : Mold 202 : Through hole
300: Insulating frame 301: Bottom plate
302: Reinforcing angle 303: Insulation
304 : Connection port 400 : Penetrating object
401: Lug 402: Earthquake spring
403 : Refractory filler 500 : Duct shaft zone
M: Shaft module

Claims (5)

A step of forming a frame frame, comprising at least one through-hole shaped body protruding from the upper and lower portions of a layer through the duct shaft zone, and being placed and fixed on a floor beam or slab of the layer around the duct shaft zone;
A step of forming a slab frame that is fitted into the duct shaft zone and includes at least one through hole through which the through-hole material passes;
A step of connecting the above frame body and the slab body, and then pouring concrete into the slab body except for the penetration hole to form a plurality of shaft modules installed on each floor;
A step of inserting the shaft module into a duct shaft zone of one of the layers, and pouring concrete between the duct shaft zone and the slab frame to allow curing; and
A stationary shaft modularization method for interlayer through-hole granules, characterized by including a step of curing by inserting each of the above shaft modules in each duct shaft zone of each layer, and connecting them as one by welding a non-penetrating granule between the through-hole granules protruding from the upper and lower portions of each layer. A step of forming a frame frame, comprising at least one through-hole shaped body protruding from the upper and lower portions of a layer through the duct shaft zone, and being placed and fixed on a floor beam or slab of the layer around the duct shaft zone;
A step of forming a slab frame that is fitted into the duct shaft zone and includes at least one through hole through which the through-hole material passes;
A step of connecting the above frame body and the slab body, and then pouring concrete into the slab body except for the penetration hole to form a plurality of shaft modules installed on each floor;
A step of inserting one of the above shaft modules into a duct shaft zone of one of the above layers, and pouring concrete between the duct shaft zone and the slab frame to allow curing; and
A stationary shaft modularization method for interlayer penetrating granular materials, characterized by including a step of inserting a non-penetrating granular material into a duct shaft zone of another layer directly above one of the above layers so that its lower end is connected to the upper end of the penetrating granular material by welding, then inserting another shaft module into the duct shaft zone of the other layer and curing it, and repeating the process of welding the penetrating granular material at the lower end to the upper end of the non-penetrating granular material for each layer. In claim 1 or 2,
The above frame body includes a plurality of earthquake-resistant springs that support a plurality of lugs formed radially on the outer surface of the above penetrating member,
A stationary shaft modularization method for interlayer penetrating granules, characterized in that a refractory filler is filled between the above-mentioned penetrating hole and the above-mentioned penetrating granules. In claim 1 or 2,
A stationary shaft modularization method for interlayer penetrating granular materials, characterized in that it includes an insulating frame that blocks the open lower portion of the slab frame except for the above penetration hole to allow concrete to cure inside, and whose outer surface extends to the inner surface of the duct shaft zone to support the pouring of concrete between the slab frame and the duct shaft zone. In claim 1 or 2,
The above shaft module is configured such that the frame frame and the slab frame are separated and symmetrically paired according to the size of the duct shaft zone.
A stationary shaft modular construction method for interlayer penetrating granular materials, characterized in that the opposing surfaces of the above frame body are connected as one by bolts at the construction site.