JP7031820B2 - Unit building - Google Patents

Description

The present invention relates to a unit building.

In the unit building disclosed in Patent Document 1, when a plurality of building units are separated and installed in the direction from the roof side to the eaves, the building side roof unit is raised to the building unit that supports the building side roof unit. A raising member is installed. As a result, the roof surfaces of the ridge-side roof unit and the eaves-side roof unit are installed without steps from the ridge to the eaves, and the roof surfaces can be made continuous and the same slope surface.

Japanese Unexamined Patent Publication No. 9-302780

However, in the unit building disclosed in Patent Document 1, since the roof surface is made to have the same continuous slope surface, it is necessary to raise the roof surface according to the separation distance (separation span) of the building unit, and there are variations in the members. Will increase.

It is an object of the present invention to provide a unit building that can cope with an increase in the variation of the separation span without increasing the height variation of the unit roof frame.

The unit building according to the first aspect is the underwater building unit, the underwater building unit separated from the underwater building unit, and the underwater roof installed on the underwater building unit. The frame, the water-up roof frame installed on the water-up building unit, the detached roof frame installed between the water-side roof frame and the water-up roof frame, and the water-side side. It is a unit building including a roof frame, a water upper roof frame, and a land roof installed on a detached roof frame, and the slopes of the underwater roof frame and the water upper roof frame are the same. The slope of the separated roof frame is different from the slope of the underwater roof frame and the above-water roof frame.

In this aspect, a unit roof frame (water-side roof frame and water-top roof frame) is installed on each of the building units (water-side building unit and water-top building unit) that are separated from each other. A separate roof frame is installed between the unit roof frames. Then, a flat roof is installed on these three roof frames (underwater roof frame, underwater roof frame and detached roof frame).

Here, if the gradient of the unit roof frame (underwater roof frame and the underwater roof frame) and the gradient of the detached roof frame have the same design, the detached span (underwater building unit) It is necessary to increase not only the variation of the detached roof frame but also the height variation of the unit roof frame according to the increase of the variation (distance from the waterside building unit). This is because it is necessary to match the height difference between the roof frames of the unit portions adjacent to each other across the separation portion to the height difference according to the separation span.

On the other hand, in this aspect, the slope of the unit roof frame and the slope of the separated roof frame are different.
Therefore, for example, it is only necessary to increase the variation (variation of width and slope) of the roof frame of the separated portion while keeping the height difference of the roof frames of the unit portions adjacent to each other across the separated portion.
That is, even if the variation of the separation span increases, it is possible to cope with it without increasing the height variation of the roof frame of the unit portion.

In the unit building according to the first aspect, the slope of the detached roof frame is steeper than the slope of the underwater roof frame and the water upper roof frame in the unit building according to the second aspect. ..

In this aspect, the slope of the detached roof frame is steeper than the slope of the unit roof frame (underwater roof frame and water side roof frame). Therefore, it is suitable when the separation span is narrower than the width of the building unit.

The unit building according to the third aspect is the unit building according to the second aspect, wherein the flat roof is configured to include a detached roof base material fixed to the detached roof frame, and the detached portion. The underwater end of the roof base material is located on the underwater roof frame, and the water upper end of the detached roof base material is located on the underwater roof frame. The water upper end portion of the standing roof base material is fixed to the water upper roof frame.

In this aspect, the flat roof is configured to include a detached roof base material fixed to the detached roof frame. The underwater end of the detached roof base material is located on the underwater roof frame, and the underwater end of the detached roof undercoat is located on the underwater roof frame. Since the slope of the roof frame of the separation portion is steeper than the slope of the roof frame on the underwater side and the roof frame on the water upper side, there is a possibility that the water upper end portion of the roof base material of the separation portion may be lifted.
Here, in this aspect, the water upper end portion of the separated roof base material is fixed to the water upper roof frame. For this reason, it is suppressed that the water upper end portion of the roof base material of the separated portion is lifted.

The unit building according to the fourth aspect is the unit building according to the second aspect, wherein the flat roof is on the detached roof base material fixed to the detached roof frame and the detached roof frame. The water-upper end portion of the detached part dew-proof heat insulating material is fixed to the water-up roof frame by a disc plate and screws.

In this aspect, the flat roof is configured to include a detached roof base material fixed to the detached roof frame and a detached dew-proof heat insulating material installed on the detached roof frame. There is.
Here, in this aspect, the water upper end portion of the detached portion dew-proof heat insulating material is fixed to the water upper roof frame by a disc plate and a screw. For this reason, it is suppressed that the water upper end portion of the dew-proof heat insulating material in the separated portion is lifted.

The unit building according to the fifth aspect is the unit building according to the third aspect, wherein the flat roof is on the detached roof base material fixed to the detached roof frame and the detached roof frame. The water-upper end portion of the detached part dew-proof heat insulating material is fixed to the water-up roof frame by a disc plate and screws.

In this aspect, the flat roof is configured to include a detached roof base material fixed to the detached roof frame. The underwater end of the detached roof base material is located on the underwater roof frame, and the underwater end of the detached roof undercoat is located on the underwater roof frame.
Further, the flat roof is configured to include a dew-proof insulation material installed on the roof frame of the retreat.
Since the slope of the roof frame of the separation part is steeper than the slope of the roof frame on the underwater side and the roof frame on the water side, both the roof base material of the separation part and the water upper end of the dew-proof insulation material of the separation part are both. There is a risk of floating.
Here, in this embodiment, the water upper end portion of the detached part roof base material is fixed to the water upper roof frame, and the water upper end portion of the detached portion dew-proof heat insulating material is above the water by a disc plate and a screw. It is fixed to the side roof frame. For this reason, it is suppressed that the water upper end portion of the detached part roof base material and the detached portion dew-proof heat insulating material is lifted.

The unit building according to the sixth aspect is the unit building according to the fifth aspect, in which the detached roof base material is fixed to the underwater end and the underwater end of the detached roof frame. The detached portion dew-proof heat insulating material is fixed to the water-lower end portion and the water-upper end portion of the detached portion roof frame.

In the unit building according to the sixth aspect, the detached roof base material is also fixed to the underwater end and the water upper end of the detached roof frame, and the detached dew-proof heat insulating material is detached. It is also fixed to the underwater end and the water upper end of the room root frame. For this reason, the followability of the detached roof base material and the detached dew-proof heat insulating material constituting the flat roof to the roof frame is further improved.

In the unit building according to the seventh aspect, the slope of the detached roof frame is zero in the unit building according to the first aspect.

In this embodiment, since the slope of the separated roof frame is zero, it is not necessary to increase the slope variation of the separated roof frame even if the variation of the separated span increases.

As described above, the unit building according to the present invention has an excellent effect that even if the variation of the separation span increases, the height variation of the unit roof frame can be dealt with without increasing.

It is a perspective view which shows the building unit. It is an exploded perspective view which shows the underwater side building unit and the underwater side building unit separated from each other together with the underwater side (unit part) roof frame. It is an exploded side view which shows the building unit, the unit part roof frame and the detached part roof frame. It is a side view of the assembled state corresponding to FIG. It is sectional drawing which shows the state around the detached part with the flat roof installed. (A) is a schematic diagram showing a unit building of a comparative example, and (B) is a schematic diagram showing a unit building of the present invention. It is a schematic diagram which shows the unit building which the separation part is not set.

Hereinafter, the unit building according to the embodiment of the present invention will be described with reference to FIGS. 1 to 7.

(Building unit 10)
FIG. 1 is a schematic perspective view showing a building unit 10. As shown in FIG. 1, the building unit 10 is formed in a rectangular parallelepiped shape, and includes columns 11, floor girders 12, and ceiling girders 13. Four pillars 11 are provided corresponding to the four corners of the rectangular building unit 10 in a plan view, and the vertical direction is the longitudinal direction thereof. The floor girder 12 has its longitudinal direction oriented horizontally, and connects the lower ends of the four pillars 11. The ceiling girder 13 has its longitudinal direction oriented horizontally, and connects the upper ends of the four pillars 11. The building unit 10 has a rectangular shape in which the length of one side is longer than the length of the other side in a plan view, and the four ceiling girders 13 are a pair of long-sided ceiling girders 13 facing in the X direction. And a pair of short-sided ceiling girders 13 facing in the Y direction.

The pillar 11 has a closed cross-sectional structure having a rectangular cross section. On the other hand, the cross-sectional shapes of the floor girder 12 and the ceiling girder 13 are substantially U-shaped (so-called groove shape) open to the inside in the horizontal direction (inside of the building unit 10). That is, as shown in FIG. 3, the ceiling girder 13 includes a web 13c that vertically connects the upper plate portion 13a, the lower plate portion 13B, and the outer end portions of the upper plate portion 13a and the lower plate portion 13B. It is composed of.

As shown in FIGS. 2 and 3, building units 10 (underwater building unit 10A and underwater building unit 10B) having the same configuration as each other are separated from each other. The underwater building unit 10A and the underwater building unit 10B are installed so that the long-sided ceiling girders 13 face each other in parallel. The separation distance D between the underwater building unit 10A and the underwater building unit 10B (that is, the distance D between the webs 13c of the long-side ceiling girders 13 facing each other, see FIG. 3) is the X direction of the building unit 10 itself (see FIG. 3). It is smaller than the dimension W (that is, the distance W between the webs 13c of the long-side ceiling girder 13 facing the X direction, see FIG. 3) in the short side direction). The height positions of the upper plate portion 13a of the ceiling girder 13 of the underwater building unit 10A and the upper plate portion 13a of the ceiling girder 13 of the water upper building unit 10B are the same.

(Unit roof frame 20A, 20B)
A unit roof frame 20A and a unit roof frame 20B are installed on the underwater building unit 10A and the underwater building unit 10B, respectively. The unit roof frame 20A and the unit roof frame 20B have similar configurations to each other.

The unit roof frames 20A and 20B include a roof beam 21, a underwater bracket 22, and a underwater bracket 23.

The roof beam 21 is a long member that supports the flat roof 40 described later. The underwater bracket 22 is provided at the end of the roof beam 21 on the longitudinal side (hereinafter, simply referred to as the underwater side), and the roof beam 21 is provided on the longitudinal underwater side (hereinafter, simply referred to as the underwater side). ) Is provided with a water upper bracket 23. The underwater bracket 22 is fixed to the underwater side of the long side ceiling girders 13 facing each other in the building unit 10, and the water side bracket 23 is attached to the water side of the long side ceiling girders 13 facing each other in the building unit 10. Is fixed to. As a result, as shown in FIG. 4, the roof beam 21 is arranged between the long-sided ceiling beams 13 and 13 facing each other.

The roof beam 21 is specifically a steel pipe having a rectangular cross section. The upper surface 21a of the roof beam 21 is regarded as a "flat roof support portion" that supports the flat roof 40.

The underwater bracket 22 is a long member having an L-shaped cross section. The underwater bracket 22 includes a flat plate-shaped first plate portion 22a whose plate thickness direction is directed in the vertical direction and a flat plate-shaped second plate portion 22b whose plate thickness direction is directed in the horizontal direction (specifically, the X direction). , Consists of. The first plate portion 22a is a "unit fixing portion" fixed to the building unit 10. The second plate portion 22b is referred to as a "beam joint portion" to be joined to the longitudinal end portion of the roof beam 21. The first plate portion 22a, which is a unit fixing portion, is mounted on the upper surface of the upper plate portion 13a of the girder 13 of the building unit 10, and in the mounted state, the first plate portion 22a is mounted on the upper plate portion 13a by the fastening member F1 (see FIG. 5). It is fixed. The second plate portion 22b, which is a beam joining portion, is joined to the roof beam 21 by welding.

Of the unit roof frames 20A and 20B, the underwater bracket 22 of the underwater unit roof frame 20A is at an angle of approximately 90 degrees downward from the end of the first plate 22a on the beam side. It is a so-called downward bracket that is bent to form a second plate portion 22b.
On the other hand, the underwater bracket 22 of the unit roof frame 20B on the water side is bent upward at an angle of approximately 90 degrees from the end of the first plate portion 22a on the beam side, and the second plate portion 22b is formed. It is a so-called upward bracket formed.

The water upper bracket 23 is a long member having an L-shaped cross section. The water upper bracket 23 includes a flat plate-shaped first plate portion 23a whose plate thickness direction is directed to the vertical direction, and a flat plate-shaped second plate portion 23b whose plate thickness direction is directed to the horizontal direction (specifically, the X direction). It is composed of. The first plate portion 23a is a "unit fixing portion" fixed to the building unit 10. The second plate portion 23b is referred to as a "beam joint portion" to be joined to the longitudinal end portion of the roof beam 21. The first plate portion 23a, which is a unit fixing portion, is mounted on the upper surface of the upper plate portion 13a of the girder 13 of the building unit 10, and in the mounted state, the first plate portion 23a is mounted on the upper plate portion 13a by the fastening member F1 (see FIG. 5). It will be fixed. The second plate portion 23b, which is a beam joining portion, is joined to the roof beam 21 by welding.

Of the unit roof frames 20A and 20B, the water side bracket 23 of the unit roof frame 20A on the water side is bent downward at an angle of approximately 90 degrees from the end portion of the first plate portion 23a on the beam side. It is a so-called downward bracket on which the second plate portion 23b is formed.
On the other hand, the water side bracket 23 of the water side unit roof frame 20B is bent upward from the end of the first plate part 23a on the beam side at an angle of approximately 90 degrees to form the second plate part 23b. It is a so-called upward bracket.

As shown in FIG. 2, a plurality of roof beams 21 are provided in parallel in the Y direction. The unit roof frames 20A and 20B are formed in a ladder shape by a plurality of roof beams 21, the underwater bracket 22, and the underwater bracket 23.

As shown in FIG. 4, in a state where the unit roof frames 20A and 20B are fixed to the building units 10A and 10B, the roof beams 21 and 21 have an angle in which the longitudinal direction thereof is inclined with respect to the horizontal direction. There is a slight downward slope from the upper side of the water to the lower side of the water. Therefore, the water upper end portion of the upper surface 21a (flat roof support portion) of the roof beam 21 is higher than the water lower end portion of the upper surface 21a (flat roof support portion) of the roof beam 21. The gradient of the roof beam 21 of the underwater roof frame 20A and the gradient of the roof beam 21 of the underwater roof frame 20B are the same gradient a. Further, the longitudinal direction of the roof beams 21 and 21 is parallel to the short-sided ceiling girders 13 of the building units 10A and 10B and perpendicular to the long-sided ceiling girders 13 of the building units 10A and 10B in a plan view.

(Release roof frame 30)
A detached roof frame 30 is installed between the underwater roof frame 20A and the underwater roof frame 20B.

The detached roof frame 30 includes a connecting roof beam 31, a water bracket 32, and a water bracket 33.

The connecting roof beam 31 is a long member, specifically, a steel pipe having a rectangular cross section. The upper surface 31a of the connecting roof beam 31 functions as a “roof support portion” that supports the flat roof 40.

The underwater bracket 32 is provided at the underwater end of the connecting roof beam 31, and the underwater bracket 33 is provided at the underwater end of the connecting roof beam 31. The underwater bracket 32 is fixed to the girder 13 of the underwater building unit 10A, and the underwater bracket 33 is fixed to the girder 13 of the underwater building unit 10B. As a result, the connecting roof beam 31 is arranged with its longitudinal direction oriented substantially in the X direction. Specifically, the longitudinal direction of the connecting roof beam 31 is set to an angle that is parallel to the X direction in a plan view and is inclined with respect to the X direction in a side view, specifically, an angle that the lower side of the water is lower and the upper side of the water is higher. Will be done.

As shown in FIG. 3, the underwater side bracket 32 includes a underwater side support bracket 34 and a underwater side receiving bracket 35. Further, the water upper bracket 33 is configured to include a water upper support bracket 36, a water upper receiving bracket 37, and water.

The support brackets (underwater side support bracket 34, water upper support bracket 36) include girder fixing portions 34b and 36b fixed to the ceiling girder 13 of the building unit 10, and the receiving bracket (water side receiving bracket 35, water upper receiving bracket). It has bracket fixing portions 34a and 36a fixed to the bracket 37).

The girder fixing portions 34b and 36b and the bracket fixing portions 34a and 36a are both flat plates. The upper ends of the girder fixing portions 34b and 36b and the end portions of the bracket fixing portions 34a and 36a are connected via a bent portion bent at a right angle of approximately 90 degrees. As a result, the support brackets 34 and 36 are long members having an L-shaped cross section. The girder fixing portions 34b and 36b are fixed to the web 13c by a fastening member F2 (see FIG. 5) in a state of being overlapped with the outer surface (outer surface of the building unit 10) of the web 13c of the ceiling girder 13. The bracket fixing portion 34a of the underwater support bracket 34 and the bracket fixing portion 36a of the underwater support bracket 36 both have the vertical direction as the plate thickness direction and are located at the same height.

The receiving brackets 35 and 37 are long members arranged with the longitudinal direction facing the Y direction, and are long members having an L-shaped cross section.

Specifically, the underwater receiving bracket 35 has a flat plate-shaped first plate portion 35a whose plate thickness direction is directed in the vertical direction and a flat plate-shaped plate-shaped portion 35a whose plate thickness direction is directed in the horizontal direction (specifically, the X direction). It is composed of a second plate portion 35b. The first plate portion 35a and the second plate portion 35b are connected to each other via a bent portion formed at the end portion of the first plate portion 35a on the beam side. The first plate portion 35a is referred to as a "bracket fixing portion" to be fixed to the underwater support bracket 34. The second plate portion 35b is referred to as a "beam joint portion" to which the connecting roof beam 31 is joined. The first plate portion 35a is fixed to the first plate portion 34a of the support bracket 34 by the fastening member F3 (see FIG. 5) in a state of being mounted on the first plate portion 34a of the support bracket 34. The underwater receiving bracket 35 is a so-called downward bracket.
Specifically, the water upper receiving bracket 37 has a flat plate-shaped first plate portion 37a whose plate thickness direction is directed in the vertical direction and a flat plate-shaped portion whose plate thickness direction is directed in the horizontal direction (specifically, the X direction). It is composed of the second plate portion 37b of the above. The first plate portion 37a and the second plate portion 37b are connected to each other via a bent portion formed at the end portion of the first plate portion 37a on the beam side. The first plate portion 37a is referred to as a "bracket fixing portion" to be fixed to the underwater support bracket 36. The second plate portion 37b is referred to as a "beam joint portion" to which the connecting roof beam 31 is joined. The first plate portion 37a is fixed to the first plate portion 36a of the water upper support bracket 36 by a fastening member F3 (see FIG. 5) in a state of being mounted on the first plate portion 36a of the water upper support bracket 36. .. The water upper receiving bracket 37 is a so-called upward bracket.

The first plate portion 35a of the underwater receiving bracket 35 and the first plate portion 37a of the underwater receiving bracket 37 both have the vertical direction as the plate thickness direction and are located at the same height.
On the other hand, the connecting roof beam 31 of the detached roof frame 30 has its longitudinal direction oriented at an angle inclined with respect to the X direction in a side view. As a result, the flat roof support portion, which is the upper surface 31a of the connecting roof beam 31, has a slight downward slope from the water upper side to the water lower side. The gradient b of the connecting roof beam 31 of the separated roof frame 30 is steeper than the gradient a.

(Flat roof 40)
As shown in FIG. 5, a flat roof 40 is installed on the unit roof frame 20 and the detached roof frame 30. The flat roof 40 is configured to include a roof base material 50 and a dew-proof heat insulating material 60. The roof base material 50 is supported by the roof beam 21 of the unit roof frame 20 and the detached roof frame 30, and the flat roof support portions 21a and 31a of the upper surfaces 21a and 31a of the connecting roof beam 31. The dew-proof heat insulating material 60 is arranged on the roof base material 50.

The roof base material 50 is configured to include a plurality of roof base materials 50 that are separated from each other. Specifically, the roof base material 50 includes a detached roof base material 50C corresponding to the detached portion D, a underwater roof base material 50A corresponding to the underwater building unit 10A, and a water upper building unit 10B. It is configured to include the water upper roof base material 50B corresponding to the above.

The underwater side end portion (left end portion in FIG. 5) of the detached roof base material 50C is located above the roof beam 21 of the underwater side roof frame 20A. That is, the underwater end of the detached roof base material 50C is located below the underwater end of the roof beam 21 of the underwater roof frame 20A. The water upper end portion of the separated roof base material 50C is located above the roof beam 21 of the water upper roof frame 20B. That is, the water upper end portion of the detached roof base material 50C is located on the water upper side of the water lower end portion of the roof beam 21 of the water upper roof frame 20B.

The separation portion roof base material 50C is fixed to the separation portion roof frame 30. This fixing is performed on the connecting roof beam 31 of the detached roof frame 30 by a fixing member such as a screw (not shown). The fixed positions of the detached roof base material 50C with respect to the connecting roof beam 31 are near both ends in the longitudinal direction of the connecting roof beam 31 (near the underwater side end and near the underwater side end) and at the center in the longitudinal direction. It is said to be a position that includes.

The fixing of the roof base material 50C of the separated portion is not only fixed to the roof frame 30 of the separated portion, but also fixed to the roof frame 20A on the underwater side and fixed to the roof frame 20B on the water upper side. Fixing to the underwater roof frame 20A is performed by a fixing member 80 (see FIG. 5) such as a screw near the underwater end of the detached roof base material 50C. Fixing to the water upper roof frame 20B is performed by a fixing member 80 (see FIG. 5) such as a screw near the water upper end portion of the separated roof base material 50C.

The dew-proof heat insulating material 60 is configured to include a plurality of dew-proof heat insulating materials 60 that are separated from each other. Specifically, the dew-proof heat insulating material 60 includes a detached portion dew-proof heat insulating material 60C corresponding to the detached portion D, a water-lower side dew-proof heat insulating material 60A corresponding to the underwater building unit 10A, and a water upper side. It is configured to include a water upper dew-proof heat insulating material 60B corresponding to the building unit 10B.

The detached portion dew-proof heat insulating material 60C is fixed to the connecting roof beam 31 by the fixing member 70. The fixing member 70 is composed of a disc plate 71 and a screw 72. The disc plate 71 is arranged on the upper surface of the dew-proof heat insulating material 60, and the screw 72 penetrates the dew-proof heat insulating material 60 and the roof base material 50 and is screwed to the FR connecting beam 31. The fixing to the connecting roof beam 31 by the fixing member 70 is performed at a position including both ends in the longitudinal direction and the central portion in the longitudinal direction of the connecting roof beam 31.

The underwater end of the dew-proof heat insulating material 60C is located above the roof beam 21 of the underwater roof frame 20A and above the underwater roof base material 50A. There is. The water upper end portion of the detached portion dew-proof heat insulating material 60C is located above the roof beam 21 of the water upper roof frame 20B, and is located above the water upper roof base material 50B. As a result, the region where the dew-proof and heat insulating material 60C for the detached portion is arranged (the region in the left-right direction in FIG. 5) is wider than the region where the roof base material 50C for the detached portion is arranged.

Further, the vicinity of the water upper end portion of the detached portion dew-proof heat insulating material 60C is fixed to the roof beam 21 of the water upper roof frame 20B by a fixing member 70 (see reference numeral 70 on the right side of FIG. 5).

(procedure)
Fixing of the unit roof frames 20A and 20B to the building units 10A and 10B may be performed at the site, but is usually performed at the factory. On the other hand, the fixing of the separated roof frame 30 to the two building units 10A and 10B separated from each other is performed at the site. At this time, the support brackets 34 and 36 may be fixed to the building units 10A and 10B at the factory, and the receiving brackets 35 and 37 and the connecting roof beam 31 may be fixed to the support brackets 34 and 36 at the site. In this case, the connecting roof beam 31 and the receiving brackets 35 and 37 are joined in advance at the factory.

<Action effect>
Next, the action and effect of this embodiment will be described.

In the present embodiment, the unit roof frame 20 (water-side roof frame 20A and water-top roof frame 20B) is placed on each of the building units 10 (water-side building unit 10A and water-top building unit 10B) that are separated from each other. Is installed. A detached roof frame 30 is installed between the unit roof frames 20A and 20B. Then, the flat roof 40 is installed on these three roof frames (the underwater roof frame 20A, the underwater roof frame 20B, and the remote roof frame 30).

Here, if, as shown in FIG. 6A, the gradient of the unit roof frame 20 and the gradient of the detached roof frame 30 have the same design, the detached span D (underwater building unit) is used. As the variation of the distance D) between the roof and the water surface building unit increases, not only the variation of the detached roof frame 30 (see reference numerals 30'and 30'') but also the height variation of the unit portion roof frame 20 (reference numeral 30', 30''). See also 20B'and 20B') also need to be increased. This is because it is necessary to match the height difference of the unit roof frames 20A and 20B (20B', 20B ") adjacent to each other with the separation portion D in between to match the height difference according to the separation span D.

On the other hand, in the present embodiment, as shown in FIG. 6B, the gradient a of the unit roof frame 20 and the gradient b of the separated roof frame 30 are different.
Therefore, for example, variations of the separated roof frames 30 (see width and gradient variations, reference numerals 30 and 30') while maintaining the height difference between the unit roof frames 20A and 20B adjacent to each other with the separated portion D in between. All you have to do is increase.
That is, even if the variation of the detached span D increases, it can be dealt with without increasing the height variation (reference numerals 20A, 20B) of the unit roof frame 20.

Further, in the present embodiment, the gradient b of the detached roof frame 30 is steeper than the gradient a of the unit roof frame 20 (the underwater roof frame 20A and the underwater roof frame 20B). Therefore, it is suitable when the separation span D is narrower than the width W of the building unit.

Further, in the present embodiment, the flat roof 40 is configured to include the detached roof base material 50C fixed to the detached roof frame 30. The underwater side end of the detached roof base material 50C is located on the underwater roof frame 20A, and the water upper end of the detached roof base material 50C is located on the underwater roof frame 20B. is doing. Since the gradient b of the detached roof frame 30 is steeper than the gradient a of the underwater roof frame 20A and the underwater roof frame 20B, the water upper end portion of the detached roof base material 50C (FIG. 5). The right end) may be lifted.
Here, in the present embodiment, the water upper end portion of the detached roof base material 50C is fixed to the water upper roof frame 20B (see the fixing member 80 in FIG. 5). Therefore, it is suppressed that the water upper end portion of the detached roof base material 50C is lifted.

Further, in the present embodiment, the flat roof 40 has a detached roof base material 50C fixed to the detached roof frame 30 and a detached roof dew-proof heat insulating material 60C installed on the detached roof frame 30. And is configured to include.
Here, the water upper end portion of the detached portion dew-proof heat insulating material 60C is fixed to the water upper roof frame 20B by the disc plate 71 and the screw 72. Therefore, it is suppressed that the water upper end portion of the detached portion dew-proof heat insulating material 60C is lifted.
In this embodiment, the underwater side end portion (left end portion in FIG. 5) of the detached part dew-proof heat insulating material 60C is not fixed to the underwater side roof frame 20A, and the construction is simplified. Alternatively, the lower end of the water may be fixed.

Further, in the present embodiment, the detached roof base material 50C is fixed to the underwater end portion and the water upper end portion of the detached portion roof frame 30 (not shown), and the detached portion dew-proof heat insulating material 60C is used. , Fixed to the underwater end and the water upper end of the detached roof frame 30 (see reference numeral 70 in FIG. 5). Therefore, the followability of the detached roof base material 50C and the detached dew-proof heat insulating material 60C constituting the flat roof 40 to the roof frames 20 and 30 is further improved.

Further, as shown in FIG. 7, when the three building units 10A, 10C, and 10B are installed from the underwater side to the upper side of the water without being separated from each other, the book is placed on the lowermost underwater building unit 10A. The underwater roof frame 20A of the embodiment is installed, the underwater roof frame 20B of the present embodiment is installed on the uppermost underwater building unit 10B, and the intermediate building unit 10C has a different design. By installing the unit roof frame 20C (however, the slope a), it is possible to form a flat roof having the same water gradient from the water upper side to the water lower side.
That is, the design of the unit roof frames 20A, 20C, 20B used for the unit building in which the separation portion D is not set (see FIG. 7) is the same as the unit building of the present embodiment (building unit in which the separation portion D is set). Can be used for.

[Supplementary explanation of the above embodiment]
In the above embodiment, an example in which the separation distance D (separation span D) between the underwater building unit 10A and the underwater building unit 10B is smaller than the width dimension W of the building unit 10 itself has been described. Is not limited to this.

Further, in the above embodiment, an example in which the gradient b of the connecting roof beam 31 of the separated roof frame 30 is steeper than the gradient a of the roof beam 21 of the unit roof frame 20 has been described. The invention is not limited to this, and the gradient b may be gentler than the gradient a.
Further, the gradient b may be set to zero. In this case, the combination of reference numerals 20A and 20C and the combination of reference numerals 20C and 20B shown in FIG. 7 can be used as they are for the unit roof frames installed in the underwater building unit and the waterside building unit that are separated from each other. ..

10 Building unit 10A Underwater building unit 10B Underwater building unit 20 Unit roof frame 20A Underwater roof frame 20B Underwater roof frame 30 Separate roof frame 40 Land roof 50 Roof base material 50A Underwater roof base material 50B Water-up roof base material 50C Separation part roof base material 60 Dew-proof heat insulating material 60A Water-side dew-proof heat insulation material 60B Water-up side dew-proof heat insulation material 60C Separation part dew-proof heat insulation material D Separation part a Water-proof roof frame And the slope of the roof frame on the water side b The slope of the roof frame at the remote part

Claims (3)

Underwater building unit and
The underwater building unit and the underwater building unit separated from each other,
The underwater roof frame installed on the underwater building unit,
The water-top roof frame installed on the water-top building unit,
A detached roof frame installed between the underwater roof frame and the underwater roof frame, and
A unit building comprising the underwater roof frame, the underwater roof frame, and the flat roof installed on the detached roof frame.
The slopes of the underwater roof frame and the underwater roof frame are the same, and the slopes are the same.
The slope of the detached roof frame is steeper than the slope of the underwater roof frame and the above water roof frame.
The flat roof is configured to include a detached roof base material fixed to the detached roof frame.
The underwater end of the detached roof base material is located above the underwater roof frame.
The water upper end portion of the detached roof base material is located on the water upper roof frame.
The water upper end portion of the detached roof base material is fixed to the water upper roof frame.
Unit building. The flat roof is configured to include a detached roof base material fixed to the detached roof frame and a detached dew-proof heat insulating material installed on the detached roof frame.
The water upper end portion of the detached portion dew-proof heat insulating material is fixed to the water upper roof frame by a disc plate and screws.
The unit building according to claim 1 . The detached roof base material is fixed to the underwater end portion and the water upper end portion of the detached portion roof frame.
The detached portion dew-proof heat insulating material is fixed to the underwater end portion and the water upper end portion of the detached portion roof frame.
The unit building according to claim 2 .

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