JP2018109307A - Ceiling structure and construction method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a ceiling structure that enables easy execution of work for a ceiling, and a construction method.SOLUTION: A ceiling structure 1 according to one embodiment includes a deck plate 2 having a crest part 2a and a valley part 2b. The ceiling structure 1 comprises a penetration part 9 and a reinforcing member 7 for reinforcing the periphery of the penetration part 9. A ceiling construction method includes a step of arranging the plurality of deck plates 2 so that the penetration part 9 can be formed, and a step of arranging the reinforcing member 7 around the penetration part 9.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a ceiling structure that includes a deck plate and in which equipment is installed, and a ceiling construction method.

  Conventionally, a ceiling structure provided with a deck plate is known. Japanese Patent No. 5723755 discloses a ceiling structure of a clean room provided with a deck plate having a concave-convex shape in which concave and convex portions are alternately formed. In this ceiling structure, the plurality of deck plates are arranged side by side so as to cover the entire surface of the ceiling, and the concave and convex portions of the plurality of deck plates extend linearly in the same direction. The end close portions positioned at both ends of the deck plate in the direction in which the concave portion and the convex portion extend have a shape in which the convex portion is crushed. The height of the end close portion decreases linearly toward both ends of the deck plate.

  The ceiling structure described above includes a truss structure including a lower chord steel frame and an upper chord steel frame, and a ceiling panel is provided at a position below the lower chord steel frame. A blower with a filter is attached to the ceiling panel, and the blower with a filter is suspended from the lower chord steel frame by a suspension member. In addition, the above-mentioned publication describes that a ceiling panel may not be laid under the deck plate. In this case, the air blower with a filter is a floor-mounted air conditioner or is suspended from a lower steel frame. Be lowered.

Japanese Patent No. 5723755

  As described above, equipment such as a fan with a filter is installed in the ceiling structure, and this equipment is attached to a ceiling panel provided below the lower chord steel frame in a state of being suspended by a suspension material. Yes. Therefore, since the operation | work which arrange | positions a ceiling panel and a suspension material under a ceiling structure is needed, there exists a problem that an operation | work is complicated.

  When a ceiling panel is not laid, facilities such as a fan with a filter are limited to a floor-standing type, or are arranged in a manner to be suspended from a lower chord steel frame. Moreover, since the deck plate has peaks and valleys and is more complicated in shape than the flat plate, there is a problem that it is difficult to attach the equipment to the deck plate. Therefore, there is a problem that the ceiling construction cannot be easily performed.

  An object of this invention is to provide the ceiling structure and construction method which can perform construction of a ceiling easily.

  The ceiling structure which concerns on this invention is a ceiling structure provided with the deck plate which has a peak part and a trough part, Comprising: The penetration part and the reinforcement member which reinforces the circumference | surroundings of a penetration part are provided.

  The ceiling structure includes a deck plate having a peak portion and a valley portion. Therefore, the strength can be increased as compared with a ceiling structure made of flat plates, so that the ceiling structure and the equipment in the ceiling can be constructed from above by riding on the deck plate. Moreover, since the workers can walk on the ceiling structure due to the increased strength, construction from above can be easily performed. Moreover, this ceiling structure is provided with the penetration part and the reinforcement member which reinforces the circumference | surroundings of a penetration part. Therefore, by arranging equipment in the penetrating part, equipment such as a blower can be easily installed on the ceiling. Moreover, since this ceiling structure is provided with the reinforcement member which reinforces the circumference | surroundings of a penetration part, the situation where the intensity | strength around a penetration part falls can be avoided. Therefore, since the work can be safely performed around the penetrating part, the installation work of the equipment can be efficiently performed. Therefore, the ceiling can be easily constructed.

  Moreover, the above-mentioned ceiling structure may be provided with the plate-shaped member put on a penetration part. In this case, by installing the equipment on the plate-like member in advance, it is possible to easily install the equipment on the ceiling by placing the plate-like member on which the equipment is attached on the penetration portion. Therefore, installation of equipment from above can be easily performed.

  The reinforcing member may have a rising portion that extends upward. In this case, the strength of the reinforcing member can be increased compared to a flat reinforcing member having no rising portion. Therefore, since the strength around the penetrating portion can be further increased, the operation can be performed more safely.

  Moreover, the above-described ceiling structure may include an adjustment plate that connects the deck plate and the reinforcing member. In this case, the deck plate and the reinforcing member can be easily arranged by connecting the deck plate and the reinforcing member with the adjusting plate. Therefore, the ceiling can be constructed more easily.

  Further, the reinforcing members may be provided in a pair with respect to the portion that forms the penetrating portion of the deck plate, and the pair of reinforcing members may extend in a direction in which the peak portion and the valley portion are arranged. In this case, since the pair of reinforcing members can be disposed around the portion where the penetrating portion is formed, the periphery of the penetrating portion can be reliably reinforced. Moreover, the circumference | surroundings of a penetration part can also be reinforced in advance by arrange | positioning a pair of reinforcement member beforehand to the part which is going to form a penetration part.

  The plate-like member may be an equipment panel that supports equipment arranged on the ceiling. In this case, the installation of the equipment on the ceiling can be performed more easily by placing the equipment panel that supports the equipment on the penetrating portion.

  Moreover, you may provide the spacer interposed between an equipment panel and a reinforcement member. In this case, the equipment panel, the spacer, and the reinforcing member can be fixed by driving a screw or the like into the equipment panel and the spacer while the spacer is fixed to the reinforcing member. Moreover, since the gap is formed between the equipment panel and the reinforcing member by the spacer, it is possible to easily fill the gap with the seal member. Therefore, since the ceiling structure can be easily sealed, the ceiling can be more easily constructed.

  Further, the reinforcing member may be a CT section having a rising portion. In this case, since the reinforcing member is CT section steel, the volume of the steel material can be suppressed and the reinforcing member can be reduced in weight. Further, since the reinforcing member is a CT section steel having a rising portion, sealing or the like can be easily performed from above as compared with the case where the reinforcing member is an H-shaped steel or an I-shaped steel. Therefore, the construction of the ceiling structure can be performed more easily.

  The construction method according to the present invention is a ceiling construction method provided with a deck plate having peaks and valleys, the step of arranging a plurality of deck plates so as to form a through portion, and the periphery of the through portion And a step of disposing a reinforcing member.

  In this ceiling construction method, a plurality of deck plates having peaks and valleys are arranged. Since the ceiling structure provided with the deck plate has higher strength than the ceiling structure made of flat plate, it is possible to work on the deck plate from above. Since the strength is high, workers and the like can walk on the ceiling structure, so that construction from above can be easily performed. Further, in this construction method, a through portion is formed, and a reinforcing member is disposed around the through portion. Therefore, it is possible to easily install the equipment by arranging the equipment in the penetrating portion, and it is possible to avoid a situation where the strength around the penetrating portion is lowered by the reinforcing member. Therefore, the work can be performed safely even around the penetrating part, and the installation work of the facility can be easily performed, so that the ceiling can be easily constructed.

  Another construction method of the present invention is a ceiling construction method provided with a deck plate having peaks and valleys, and a step of arranging a deck plate and a step of arranging a reinforcing member that reinforces the periphery of the through portion And a step of forming a penetration part in the deck plate.

  Since this construction method can be a ceiling structure including a deck plate provided with a mountain part and a valley part as described above, an operator or the like can walk on the ceiling structure and perform construction from above. It can be done easily. Further, by providing the penetrating part and the reinforcing member, it is possible to easily arrange the equipment in the penetrating part and to avoid a situation in which the strength around the penetrating part is lowered. Further, in this construction method, the reinforcement member can be reliably reinforced around the part where the penetration part is formed, and the reinforcement member is arranged in advance on the part where the penetration part is to be formed. Thus, it is possible to reinforce the periphery of the penetrating portion in advance. Therefore, since the construction can be performed safely by reinforcing the periphery of the penetrating portion, the ceiling can be constructed more easily.

  According to the present invention, the ceiling can be easily constructed.

It is a top view which shows the ceiling structure which concerns on 1st Embodiment. It is the II-II sectional view taken on the line of FIG. It is a longitudinal cross-sectional view which shows a deck plate, an adjustment board, and a beam. It is a longitudinal cross-sectional view which shows a deck plate, an adjustment board, a reinforcement member, and an equipment panel. (A)-(e) is a longitudinal cross-sectional view which shows the connection structure of the reinforcement member which concerns on a modification, and an installation panel. It is a figure which shows the periphery of the pillar of the ceiling structure of FIG. It is a top view which shows an equipment panel, a beam, and a reinforcement member. It is the VIII-VIII sectional view taken on the line of FIG. It is the IX-IX sectional view taken on the line of FIG. It is a figure which shows the connection structure of a deck plate and a clean partition. It is the XI-XI sectional view taken on the line of FIG. (A) is a longitudinal cross-sectional view which shows a deck plate and illumination. (B) is the longitudinal cross-sectional view which expanded the illumination of (a). It is a longitudinal cross-sectional view which shows a deck plate and piping. It is a longitudinal cross-sectional view which shows an installation panel and illumination. (A) is a perspective view which shows the state before crushing the edge part of a deck plate. (B) is a perspective view which shows the state which crushed the edge part of (a). (C) is a side view which shows the crushed edge part of (b). It is a top view which shows the ceiling structure which concerns on 2nd Embodiment. It is a figure which shows the duct of the ceiling structure of FIG. It is a longitudinal cross-sectional view which shows the ceiling structure which concerns on a modification.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. In the description of the drawings, the same or corresponding elements are denoted by the same reference numerals, and redundant description is omitted.

(First embodiment)
FIG. 1 is a plan view showing a ceiling structure 1 according to the first embodiment. The ceiling structure 1 forms, for example, a ceiling of a clean room in which temperature and humidity are controlled to be constant and air cleanliness is ensured. As shown in FIG. 1, the ceiling structure 1 includes a plurality of deck plates 2, a plurality of equipment panels 3 (plate-like members) arranged between the deck plates 2, and beams 4 arranged in a lattice pattern. And columns 5 positioned at the intersections of the vertical and horizontal beams 4. In the ceiling structure 1, for example, the bottom surface of the deck plate 2 is exposed in a clean room.

  2 is a cross-sectional view taken along line II-II in FIG. As shown in FIGS. 1 and 2, the deck plate 2 is a corrugated steel plate having a crest 2a and a trough 2b, and the crest 2a and the trough 2b are connected to each other via an inclined portion 2k. . The plurality of deck plates 2 are arranged so that the crests 2a and the troughs 2b are alternately arranged. Hereinafter, the direction in which the peaks 2a and the valleys 2b are arranged will be described as a first direction D1, and the direction perpendicular to the first direction D1 and the peaks 2a and valleys 2b extend will be described as a second direction D2. .

  The deck plate 2 and the equipment panel 3 are alternately arranged in the first direction D1. By arranging the deck plate 2 and the equipment panel 3 alternately in this way, the deck plate 2 having high strength is located on both sides of the equipment panel 3, so that the strength around the equipment panel 3 can be increased. The plurality of equipment panels 3 are arranged so as to be aligned along the second direction D2.

  The beam 4 is a support steel material of the ceiling structure 1, and the deck plate 2 and the equipment panel 3 are arranged between the beams 4 arranged in a lattice shape. The beam 4 and the deck plate 2 are connected to each other through an adjustment plate 6. A reinforcing member 7 is disposed between the deck plate 2 and the equipment panel 3, and the periphery of the equipment panel 3 is reinforced by the reinforcing member 7.

  The equipment panel 3 is disposed in the penetrating portion 9 penetrating vertically, and is fixed so as to close the penetrating portion 9. The equipment panel 3 is an equipment penetration part that penetrates and supports equipment such as air conditioning that forms the ceiling structure 1 and has a plate shape. Here, in this specification, the “penetrating portion” includes both a portion that has already been penetrated and a portion that is to be penetrated later. Further, the “penetrating portion” is an opening formed in the process of arranging the deck plate 2 (an opening formed between the plurality of deck plates 2 and formed between the deck plate 2 and another member). Opening). “Equipment” indicates equipment installed on the ceiling, and includes lighting, a return, air conditioning such as a blower, piping, a speaker, a sensor, and an air vent. The installation structure of the equipment on the equipment panel 3 will be described in detail later.

  FIG. 3 is a longitudinal sectional view showing the deck plate 2, the adjustment plate 6, and the beam 4. The beam 4 is, for example, an H-section steel, and includes a web 4a and a flange 4b that extends in the horizontal direction at the lower end of the web 4a. A bent portion 2 c that is bent along the shape of the adjustment plate 6 is formed at the end of the deck plate 2 on the adjustment plate 6 side. The bent portion 2c is, for example, a first portion 2d folded back obliquely upward by about 120 ° with respect to the horizontal direction, and a first portion 2d folded from the first portion 2d toward the beam 4 on the tip side of the first portion 2d. Two portions 2e.

  The adjustment plate 6 has three bent portions 6 a, 6 b, 6 c at a portion away from the beam 4. The bent portion 6a is folded obliquely upward from a portion extending from the horizontal direction, and the bent portion 6b is bent toward the deck plate 2 from the upper end of the bent portion 6a. The bent portion 6c is bent along the second portion 2e. As described above, since the bent portion 6c is bent along the bent portion 2c, the connection strength between the deck plate 2 and the adjusting plate 6 is increased.

  On the upper surface of the flange 4 b of the beam 4, an adjustment plate 6 and a Z hardware 10 are fixed. In the beam 4, the adjustment plate 6 is provided along the upper surface of the flange 4b. The Z hardware 10 includes a first flat plate portion 10a arranged along the upper surface of the flange 4b, a rising portion 10b rising from the first flat plate portion 10a, and an upper end of the rising portion 10b in a direction opposite to the first flat plate portion 10a. And a second flat plate portion 10c extending.

  The Z hardware 10 is arranged on the web 4 a side with respect to the adjustment plate 6, and a seal material 11 is filled between the Z hardware 10 and the adjustment plate 6. Specifically, the sealing material 11 is filled between the upper surface of the flange 4 b, the region surrounded by the rising portion 10 b and the second flat plate portion 10 c, and the upper surface of the adjustment plate 6. As described above, the sealing material 11 is arranged between the beam 4, the adjustment plate 6 and the Z hardware 10, so that the beam 4, the adjustment plate 6 and the Z hardware 10 are fixed without a gap.

  FIG. 4 is an enlarged longitudinal sectional view of the deck plate 2, the adjustment plate 8, the reinforcing member 7, and the equipment panel 3. As shown in FIGS. 2 and 4, the reinforcing member 7 includes a rising portion 7 a extending upward. The reinforcing member 7 is, for example, a CT steel, and includes a web that forms the rising portion 7a and a flange portion 7b that extends in the horizontal direction at the lower end of the web. The rising portion 7a extends upward from the center in the first direction D1 of the flange portion 7b, whereby the reinforcing member 7 has a T-shape that is upside down.

  A bent portion 2f similar to the bent portion 2c described above is formed at the end of the deck plate 2 on the adjustment plate 8 side. The adjustment plate 8 has bent portions 8a, 8b, and 8c similar to the bent portions 6a, 6b, and 6c at a portion away from the reinforcing member 7. The adjustment plate 8 is fixed to the upper surface of the flange portion 7 b of the reinforcing member 7.

  A rising piece 8d bent upward is formed at the end of the adjustment plate 8 on the reinforcing member 7 side. A sealing material 12 is filled between the rising piece 8d, the upper surface of the flange portion 7b, and the rising portion 7a. As described above, the sealing member 12 is disposed between the rising portion 7a, the flange portion 7b, and the rising piece 8d, whereby the reinforcing member 7 and the adjustment plate 8 are fixed to each other without a gap.

  The equipment panel 3 is provided on the opposite side of the rising portion 7a to the adjustment plate 8. The equipment panel 3 is provided above the flange portion 7b, and a spacer 13 and a sealing material 14 are interposed between the equipment panel 3 and the flange portion 7b. The spacer 13 is interposed between the lower surface of the equipment panel 3 and the upper surface of the flange portion 7 b, and the sealing material 14 is provided on the penetrating portion 9 side of the spacer 13.

  A space is formed between the equipment panel 3 and the reinforcing member 7 by the spacer 13 and a sealing material 14 is filled between the equipment panel 3 and the reinforcing member 7, whereby the airtightness of the through-hole 9 of the ceiling structure 1 is achieved. It is possible to ensure the sex. The sealing material 14 is, for example, a modified silicone seal.

  In the example shown in FIG. 4, the sealing material 14 is filled from below (below the equipment panel 3). Further, the arrangement of the spacers and the sealing material interposed between the equipment panel 3 and the reinforcing member 7 is not limited to the example shown in FIG. 4 and can be appropriately changed. For example, as shown in FIG. 5A, the sealing material 14A may be arranged on the rising portion 7a side with respect to the spacer 13A. This sealing material 14 </ b> A is filled from above the reinforcing member 7.

  As shown in FIG. 5B, the sealing material 14 </ b> B may be filled in the portion on the rising portion 7 a side of the spacer 13 </ b> B and between the rising portion 7 a and the equipment panel 3. Further, as shown in FIG. 5 (c), the spacer is omitted and the lower surface of the equipment panel 3 and the upper surface of the flange portion 7 b are in close contact with each other, and a seal that is a triangular seal is provided between the rising portion 7 a and the equipment panel 3. The material 14C may be disposed.

  5D, the spacer is omitted and the lower surface of the equipment panel 3 and the upper surface of the flange portion 7b are in close contact with each other, and the sealing material 14D is disposed between the rising portion 7a and the equipment panel 3. May be. All of the sealing materials 14B, 14C, and 14D described above are filled from above the reinforcing member 7.

  Further, as shown in FIG. 5E, the lower surface of the equipment panel 3 and the upper surface of the flange portion 7b are in close contact with each other, and the side surface of the flange portion 7b and the lower surface of the equipment panel 3 are filled with the sealing material 14E from below. May be. As described above, even when the sealing materials 14 </ b> A to 14 </ b> E are arranged, it is possible to ensure the airtightness of the through portion 9 of the ceiling structure 1.

  FIG. 6 is a cross-sectional view showing a connection structure between the beam 4 and the column 5. As shown in FIG. 6, the pillar 5 is arranged between the plurality of beams 4, and a support plate 16 is attached between the outer periphery of the pillar 5 and the beam 4 so as to surround the pillar 5. Yes. An adjusting plate 6 is disposed between the two beams 4 and the pillars 5 that intersect each other, and the sealing material 11 described above is filled between the adjusting plate 6 and the beams 4. Thus, the adjusting plate 6 and the sealing material 11 can be arranged between the beam 4 and the column 5.

  FIG. 7 is a plan view showing the equipment panel 3. As shown in FIG. 7, the facility panel 3 is disposed between the two beams 4 extending in parallel with each other and the reinforcing members 7 disposed in parallel with each other in plan view. The equipment panel 3 includes, for example, an equipment support space 3a that supports equipment at the center thereof.

  FIG. 8 is a cross-sectional view taken along line VIII-VIII in FIG. 7 and shows a connection structure between the equipment panel 3 and the beam 4. As shown in FIG. 8, a spacer 18 and a sealing material 19 are interposed between the equipment panel 3 and the flange 4b. The arrangement mode of the spacer 18 and the sealing material 19 may be the same as the arrangement mode of the spacer 13 and the sealing material 14 described above or the arrangement mode of the spacers 13A and 13B and the sealing materials 14A to 14E. A space is formed between the equipment panel 3 and the flange 4b by the spacer 18 and a sealing material 19 is filled between the equipment panel 3 and the flange 4b to ensure airtightness between the equipment panel 3 and the beam 4. Has been.

  9 is a cross-sectional view taken along line IX-IX in FIG. As shown in FIG. 9, the deck plate 2, the adjustment plate 8, the reinforcing member 7, and the equipment panel 3 are fixed in a state of being aligned in the first direction D <b> 1. Since the spacer 13 and the sealing material 14 are interposed between the equipment panel 3 and the reinforcing member 7, the airtightness of the through portion 9 is ensured.

  A screw 20 is driven into the equipment panel 3 and the spacer 13 from the upper surface 3b of the equipment panel 3. The screw 20 penetrates the equipment panel 3 up and down, and attaches the equipment panel 3 to the reinforcing member 7 via the spacer 13. It is fixed to. Thus, the equipment panel 3 and the reinforcing member 7 can be fixed by the screws 20 via the spacers 13.

  FIG. 10 shows a connection structure between the deck plate 2 and the clean partition C forming the wall of the clean room. As shown in FIG. 10, between the deck plate 2 and the clean partition C, there is a U-shaped connection member 21, a steel plate 22 that seals the deck plate 2, and between the connection member 21 and the steel plate 22. And a sealing material 23 sandwiched between the two. The sealing material 23 bonds the connecting member 21 and the steel plate 22 to each other. The sealing material 23 is, for example, foam rubber, and is made of EPDM (ethylene / propylene / diene rubber). As an example, the sealing material 23 is EPT SEALER (registered trademark).

  The connection member 21 is fixed to one surface of the clean partition C and extends up and down, a second portion 21b fixed to the other surface of the clean partition C and extends up and down, and a first portion 21a and the second portion 21b, and a third portion 21c on which the lower surface of the deck plate 2 is placed.

  The lower end of the first portion 21a and the clean partition C are airtight with each other through the sealing material 24, and between the upper end of the first portion 21a (one end of the third portion 21c) and the lower surface of the deck plate 2. There is a sealing material 25 interposed. The third portion 21 c and the deck plate 2 are fixed to each other by a rivet R that is inserted into the third portion 21 c and the lower surface of the deck plate 2.

  The lower end of the second portion 21b and the clean partition C are fixed to each other by a sealing material 24 and a screw B. The steel plate 22 extends in the vertical direction from the lower end portion of the second portion 21 b to the upper side of the deck plate 2 outside the connection member 21, and has a function of closing the deck plate 2.

  11 is a cross-sectional view taken along line XI-XI in FIG. As shown in FIGS. 10 and 11, the steel plate 22 has a similar shape to the lower portion of the peak portion 2a of the deck plate 2, and is arranged so as to be fitted into the peak portion 2a from below. The sealing material 23 is disposed in a frame shape on the lower side of the deck plate 2, for example. A sealing material 26 is filled between the steel plate 22 and the lower surface of the deck plate 2, and the sealing material 26, the steel plate 22, the connecting member 21, and the clean partition C ensure airtightness of the clean partition C. .

  FIG. 12A and FIG. 12B are cross-sectional views showing a connection structure between the lighting 31 that is a kind of equipment of the ceiling structure 1 and the deck plate 2. As shown in FIGS. 12A and 12B, the illumination 31 is fixed to the lower surface of the mountain portion 2a. The illumination 31 is fixed by, for example, the deck plate 2 and a plurality of screws N. The screw N penetrates the deck plate 2 up and down, and a sealing material 27 is disposed between the upper portion of the deck plate 2 and the upper surface of the deck plate 2. With this sealing material 27, the hole of the deck plate 2 through which the screw N passes is surely closed, and airtightness is ensured.

  A packing 28 and a sealing material 29 are interposed between the illumination 31 and the lower surface of the deck plate 2. The deck plate 2 includes a hole 2g through which the wiring of the illumination 31 passes. The illumination 31 is fixed to the deck plate 2 in a state where the center in plan view is aligned with the hole 2g.

  The sealing material 29 is filled in the hole 2g, and is in close contact with the illumination 31, the wall surface of the hole 2g, and the upper surface of the deck plate 2 to ensure the airtightness of the hole 2g. A seal material 29 is filled in the hole of the packing 28, and the packing 28 is in close contact with the upper surface of the illumination 31 and the lower surface of the deck plate 2. Accordingly, the packing 28 and the sealing material 29 ensure airtightness at the position where the lighting 31 of the deck plate 2 is disposed.

  FIG. 13 is a cross-sectional view showing a connection structure between the pipe 32 and the deck plate 2 which is a kind of equipment of the ceiling structure 1. The pipe 32 penetrates the peak portion 2a of the deck plate 2 up and down, and is supported by a support member 33 fixed on the upper surface of the peak portion 2a. The support material 33 includes an upper surface of the peak portion 2a through which the pipe 32 is passed, an upper surface of the peak portion 2a adjacent to one side of the peak portion 2a through which the pipe 32 is passed, and It is placed on the upper surface of the mountain portion 2a adjacent to the other side.

  That is, since the support member 33 is disposed so as to straddle the three peak portions 2a, the support member 33 is stably disposed. A sealing material 34 is disposed on the upper side of the portion of the mountain portion 2a and the support material 33 through which the pipe 32 passes. Since the sealing material 34 is filled so as to fill the hole portion through which the pipe 32 passes, the air tightness of the portion through which the pipe 32 passes is ensured.

  FIG. 14 is a cross-sectional view showing a connection structure between the illumination panel 35 of a type different from the illumination 31 and the equipment panel 3, and shows an installation example of equipment on the equipment panel 3. A hole 3e for installing the illumination 35 is formed in the equipment panel 3, and the hole 3e is provided, for example, at the center of the equipment panel 3 in plan view.

  The illumination 35 has a main body 35a fitted in the hole 3e and an illumination part 35b exposed to the lower side of the equipment panel 3. The main body 35a is supported by a support member 36 fixed in a gate shape on the upper side of the equipment panel 3. The support member 36 is fixed to the upper surface 3 b of the equipment panel 3 and extends upward from the equipment panel 3, and a connecting part 36 b that connects upper ends of the pillars 36 a above the illumination 35. And a plurality of support portions 36c extending downward from the connection portion 36b and connected to the upper end of the main body portion 35a. A wiring 37 for supplying power to the illumination 35 extends from the main body 35a, and the wiring 37 is disposed along the upper surface 3b of the equipment panel 3. The wiring 37 is fixed to the upper surface 3b by a plurality of wiring fixing members 38, for example.

  The illumination 35 is supported by the equipment panel 3 in a state where the main body 35a is fitted in the hole 3e. The upper surface of the illumination part 35 b is in close contact with the lower surface of the equipment panel 3 via the packing 39. Specifically, a packing 39 is sandwiched between the upper surface of the illumination unit 35b and the lower surface of the facility panel 3, and the illumination 35 is installed in the state where the packing 39 is sandwiched and pulled up by the support member 36. 3 is supported. Therefore, airtightness between the equipment panel 3 and the illumination 35 is ensured by the packing 39. Note that a sealing material may be sandwiched in place of the packing 39.

  FIG. 15A to FIG. 15C are diagrams showing an end structure (end close portion) of the deck plate 2 in the second direction D2. The end of the deck plate 2 in the second direction D2 is fixed to the beam 4. Further, as shown in FIGS. 15B and 15C, the end of the deck plate 2 in the second direction D2 is downward from the upper surface of the peak portion 2a toward one end of the second direction D2. An inclined flat first inclined surface 2h and a flat second inclined surface 2j inclined downward toward one end of the second direction D2 are provided on both sides of the first inclined surface 2h in the first direction D1. The first inclined surface 2h and the pair of second inclined surfaces 2j are formed by crushing the peak portion 2a and the pair of inclined portions 2k downward. And the sealing process of the end close part is performed by filling the sealing material in the boundary part of 2 h of 1st inclined surfaces, and the 2nd inclined surface 2j.

  A construction method of the ceiling structure 1 configured as described above will be described. First, the reinforcing member 7 is attached to the beam 4. Then, the deck plate 2 is laid at a location surrounded by the beam 4 and the reinforcing member 7 (step of arranging a plurality of deck plates). At this time, as shown in FIG. 9, the deck plate 2 is connected to the reinforcing member 7 via the adjusting plate 8 and the sealing material 12 (step of arranging the reinforcing member around the penetrating portion).

  A plurality of deck plates 2 are attached to the beam 4. Specifically, as shown in FIG. 3, the Z hardware 10 is disposed on the flange 4 b of the beam 4, and the deck plate 2 is connected to the beam 4 via the sealing material 11 and the adjustment plate 6. At this time, the plurality of deck plates 2 are arranged so that the through portions 9 are formed. That is, the plurality of deck plates 2 are arranged so that the through-hole 9 is formed at the position of the equipment panel 3 in FIG.

  Then, the equipment panel 3 is placed on the flange portion 7b of the reinforcing member 7 via the spacer 13 and the sealing material 14, and a screw 20 is driven into the equipment panel 3 and the spacer 13 from above, whereby the spacer is placed on the reinforcing member 7. 13 and the equipment panel 3 are fixed. Similarly, as shown in FIG. 8, the equipment panel 3 is placed on the flange 4 b of the beam 4 via the spacer 18 and the sealing material 19, and the spacer 18 and the equipment panel 3 are fixed to the beam 4.

  In addition, before installing the equipment panel 3 on the beam 4 or the reinforcing member 7, as shown in FIG. 14, the equipment such as the illumination 35 may be installed on the equipment panel 3 in advance. In this case, after the installation panel 3 is installed, the installation of the facility can be completed only by installing the wiring 37 from the illumination 35.

  In addition to the above work, as shown in FIGS. 10, 12 and 13, the clean partition C and the deck plate 2 are connected, the lighting 31 is installed on the deck plate 2, and the deck plate 2 is connected. The piping 32 is installed. As described above, the installation of the ceiling structure 1 is completed after the placement of the equipment panel 3 and the installation of various equipment on the deck plate 2.

  Next, the effects of the ceiling structure 1 and the construction method according to the present embodiment will be described. As shown in FIG. 2, the ceiling structure 1 includes a deck plate 2 having a peak portion 2a and a valley portion 2b. Therefore, since the strength can be increased as compared with a flat ceiling member, the ceiling structure 1 can be constructed from above by riding on the deck plate 2.

  Moreover, since the operator etc. can walk on the ceiling structure 1 by the intensity | strength being raised, construction from upper direction can be performed easily. Further, the ceiling structure 1 includes a penetrating portion 9 and a reinforcing member 7 that reinforces the periphery of the penetrating portion 9. Therefore, by arranging the equipment in the penetrating portion 9, the equipment such as the illumination 35 can be easily arranged on the ceiling.

  Moreover, since the ceiling structure 1 includes the reinforcing member 7 that reinforces the periphery of the through portion 9, a situation in which the strength around the through portion 9 is reduced can be avoided. Therefore, since the work can be performed safely even around the penetrating part 9, the installation work of the equipment can be performed efficiently. Therefore, the ceiling can be easily constructed.

  Further, the ceiling structure 1 includes an equipment panel 3 that is placed on the penetrating portion 9. Therefore, by attaching the equipment to the equipment panel 3 in advance, the equipment panel 3 to which the equipment is attached can be placed on the through-hole 9 and the equipment can be easily arranged on the ceiling. Therefore, installation of equipment from above can be easily performed.

  The reinforcing member 7 has a rising portion 7a extending upward. Therefore, the strength of the reinforcing member 7 can be increased compared to a flat reinforcing member having no rising portion. Therefore, since the strength around the penetrating portion 9 can be further increased, the work can be performed more safely.

  As shown in FIG. 9, the ceiling structure 1 includes an adjustment plate 8 that connects the deck plate 2 and the reinforcing member 7. Therefore, the deck plate 2 and the reinforcing member 7 can be easily disposed by connecting the deck plate 2 and the reinforcing member 7 with the adjusting plate 8. Therefore, the ceiling can be constructed more easily.

  Moreover, the spacer 13 interposed between the equipment panel 3 and the reinforcing member 7 is provided. Therefore, the equipment panel 3, the spacer 13, and the reinforcing member 7 can be fixed by driving the screws 20 into the equipment panel 3 and the spacer 13 in a state where the spacer 13 is fixed to the reinforcing member 7. In addition, since a gap is formed between the equipment panel 3 and the reinforcing member 7 by the spacer 13, the sealing material 14 can be easily filled in the gap. Therefore, since the ceiling structure 1 can be easily sealed, the ceiling can be constructed more easily.

  The reinforcing member 7 is a CT section having a rising portion 7a. Therefore, when the reinforcing member 7 is a CT steel, the volume of the steel material can be suppressed and the reinforcing member 7 can be reduced in weight. Further, since the reinforcing member 7 is a CT section steel provided with a rising portion 7a, sealing or the like can be easily performed from above as compared with the case where the reinforcing member is an H section steel or an I section steel. Therefore, the ceiling can be constructed more easily.

(Second Embodiment)
Next, a ceiling structure 41 and a construction method according to the second embodiment will be described with reference to FIGS. The ceiling structure 41 according to the second embodiment includes a deck plate 42, a reinforcing member 47, and a penetrating portion 49 that are different from the deck plate 2, the reinforcing member 7, and the penetrating portion 9.

  In the first embodiment, the plurality of deck plates 2 are arranged so that the through portions 9 are formed, but in the second embodiment, the deck plates 42 having no holes are arranged, and the through portions 49 are formed afterwards. To do. Therefore, when the deck plate 42 is disposed, the through portion 49 is not formed, and the through portion 49 is formed according to the necessity of subsequent installation of the equipment. Below, the description which overlaps with 1st Embodiment is abbreviate | omitted suitably.

  As shown in FIGS. 16 and 17, the deck plate 42 includes a penetrating portion 49 that is a facility placement planned position and a reinforcing member 47 provided in a pair with respect to the penetrating portion 49. The penetrating part 49 is sized to include a peak part 42a of the deck plate 42 and at least a part of the valley part 42b. For example, a duct 50 vertically penetrates the through portion 49.

  As shown in FIG. 16, the pair of reinforcing members 47 extend in the first direction D1 in which the peak portions 42a and the valley portions 42b of the deck plate 42 are arranged. For example, the reinforcing member 47 is disposed on both sides of the penetrating portion 49 in the second direction D2. Further, the pair of reinforcing members 47 are disposed so as to be parallel to each other, for example. Each reinforcing member 47 is, for example, an L-shaped angle.

  A construction method of the ceiling structure 41 according to the second embodiment will be described. First, the deck plate 42 having the peak portions 42a and the valley portions 42b is arranged (step of arranging the deck plate). Thereafter, a pair of reinforcing members 47 are arranged so as to sandwich the position of the penetrating portion 49 (step of arranging the reinforcing member), and the penetrating portion 49 is formed (step of forming the penetrating portion).

  The step of forming the through-hole 49 may be executed after the step of arranging the reinforcing member 47. If there is a scaffold or a support member, the through-portion 49 is formed before the step of arranging the reinforcing member 47. You may perform the process to perform. However, it is preferable to form the through portion 49 after the step of arranging the reinforcing member 47 because the deck plate 42 can be reinforced in advance and the safety is further enhanced.

  As described above, in the ceiling structure 41 and the construction method according to the second embodiment, the reinforcing member 47 is provided in a pair with respect to the portion that forms the penetrating portion 49, and the pair of reinforcing members 47 includes the mountain portion 42 a and the valley portion 42 b. Are provided so as to extend in the first direction D1 in which are arranged. Accordingly, since the pair of reinforcing members 47 can be arranged around the portion where the through portion 49 is formed, the periphery of the through portion 49 can be reliably reinforced. In addition, since a pair of reinforcing members 47 can be arranged in advance in the portion where the through portion 49 is formed, the periphery of the through portion 49 can be reinforced in advance before the through portion 49 is formed.

  As mentioned above, although each embodiment of the present invention was described, the present invention is not limited to each above-mentioned embodiment, changes in the range which does not change the gist described in each claim, or changes to others. It may be applied. That is, the present invention can be variously modified without changing the gist of each claim.

  For example, in the first embodiment described above, the example in which the plate-like member placed on the penetrating portion 9 is the equipment panel 3 has been described. However, the plate-like member is not limited to the equipment panel 3 and can be changed as appropriate. For example, as shown in FIG. 18, instead of the equipment panel 3, a sheet plate 53 that is thinner than the equipment panel 3 and made of aluminum and resin may be provided. The sheet plate 53 is, for example, Alpolic (registered trademark). Further, instead of the equipment panel 3, a deck plate similar to the deck plates 2 and 42 may be used as the plate member. Thus, the shape of the plate-like member is not limited to a flat plate shape, and may have irregularities. Further, the shape, size, arrangement, number and material of the plate-like member can be appropriately changed.

  Moreover, although the above-mentioned embodiment demonstrated the reinforcement member 7 which is CT shape steel, the shape of a reinforcement member is not restricted to CT shape steel, and can be changed suitably. For example, the reinforcing member may have a falling part downward, or may be a square member. The size, arrangement, number, and material of the reinforcing members can be changed as appropriate. Further, the shape, size, arrangement, number, and material of the deck plate and the adjustment plate are not limited to the above-described embodiments, and can be appropriately changed.

  Moreover, in the above-mentioned embodiment, the ceiling structure 1 which comprises the ceiling of a clean room was demonstrated. However, the ceiling structure and construction method according to the present invention can also be applied to structures other than clean rooms.

DESCRIPTION OF SYMBOLS 1,41 ... Ceiling structure, 2,42 ... Deck plate, 2a, 42a ... Mountain part, 2b, 42b ... Valley part, 2c, 2f ... Bending part, 2d ... 1st part, 2e ... 2nd part, 2g ... Hole Part, 2h ... first inclined surface, 2j ... second inclined surface, 2k ... inclined part, 3 ... equipment panel, 3a ... equipment support space, 3b ... upper surface, 3e ... hole, 4 ... beam, 5 ... column, 6 , 8 ... Adjustment plate, 6a, 6b, 8a, 8b ... Bending part, 7, 47 ... Reinforcing member, 7a ... Rising part, 7b ... Flange part, 8c ... Rising piece, 9, 49 ... Penetration part, 10 ... Z hardware DESCRIPTION OF SYMBOLS 10a ... 1st flat plate part, 10b ... Rising part, 10c ... 2nd flat plate part, 11, 12, 14, 14A, 14B, 14C, 14D, 14E, 19, 24-27, 29, 34 ... Sealing material, 13 , 13A, 13B, 18 ... spacer, 16 ... support plate, 20 Screws, 21 ... connecting members, 21a ... first part, 21b ... second part, 21c ... third part, 22 ... steel plate, 23 ... sealing material, 28, 39 ... packing, 31, 35 ... lighting, 32 ... piping, 33 ... Support material, 35a ... Main body part, 35b ... Illumination part, 36 ... Support member, 36a ... Column part, 36b ... Connection part, 36c ... Support part, 37 ... Wiring, 38 ... Wiring fixing member, 50 ... Duct, 53 ... sheet plate, B ... screw, C ... clean partition, D1 ... first direction, D2 ... second direction, N ... screw, R ... rivet.

Claims (10)

A ceiling structure having a deck plate having a peak and a valley,
A penetrating part,
A reinforcing member that reinforces the periphery of the penetrating portion;
With ceiling structure. A plate-like member placed on the penetrating portion;
The ceiling structure according to claim 1. The reinforcing member has a rising portion extending upward,
The ceiling structure according to claim 1. An adjustment plate for connecting the deck plate and the reinforcing member;
The ceiling structure according to claim 1. The reinforcing members are provided in a pair with respect to a portion of the deck plate that forms the penetrating portion, and the pair of reinforcing members extend in a direction in which the peak portion and the valley portion are arranged.
The ceiling structure according to claim 1. The plate-like member is an equipment panel that supports equipment arranged on the ceiling.
The ceiling structure according to claim 2. A spacer interposed between the equipment panel and the reinforcing member;
The ceiling structure according to claim 6. The reinforcing member is a CT section provided with the rising portion.
The ceiling structure according to claim 3. A ceiling construction method including a deck plate having a mountain and a valley,
Arranging a plurality of the deck plates so as to form through portions;
Arranging a reinforcing member around the penetrating portion;
Construction method with A ceiling construction method including a deck plate having a mountain and a valley,
Placing the deck plate;
Arranging a reinforcing member that reinforces the periphery of the penetrating part;
Forming the penetrating portion in the deck plate;
Construction method with

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