JP5615036B2 - How to transport building units - Google Patents

Description

The present invention relates to a method of transporting building units that make up the unitary building.

As is well known, a unit type building is constructed by arranging a plurality of box-shaped building units in combination. The building unit is formed of a substantially rectangular parallelepiped frame from a plurality of columns, a plurality of ceiling beams that connect the upper ends of these columns, and a plurality of floor beams that connect the lower ends of the columns. In addition, an outer wall material is attached to the framework as needed (see, for example, Patent Document 1).
Building units manufactured at a factory are transported to a building site by a truck or the like, and a unit type building is constructed by combining these building units side by side using a crane or the like.

JP 2009-35991 A

By the way, since the building unit is transported to the site by truck, the height of the building unit itself is restricted by the restriction of the height of the truck load, and the ceiling height cannot be made higher than a predetermined height.
Moreover, since the building unit has a large internal space, when this building unit is transported by a truck or a transport ship, a useless space in the interior is also transported, resulting in poor transportation efficiency.

The present invention has been made in view of the above problem and an object thereof is to provide a method for transporting building units that can be increasing the height of the building unit, and improving transportation efficiency.

In order to solve the above-mentioned problem, the invention described in claim 1 is, for example, as shown in FIGS. 1, 4, and 5, a plurality of pillars 2 and a plurality of joints connecting the upper ends of these pillars 2 to each other. In the method of transporting a building unit 1 that disassembles and transports a building unit 1 that includes a ceiling beam 3 of a book and a plurality of floor beams 4 that connect the lower ends of the pillars 2,
The building unit 1 includes an upper unit 10 provided with an upper column member 2a projecting downward at a corner of an upper frame 12 in which the ceiling beam 3 is assembled in a frame shape,
A lower unit 11 provided with a lower column member 2b projecting upward at a corner of a lower frame 13 in which the floor beam 4 is assembled in a frame shape;
A column body 2c provided between the upper column member 2a and the lower column member 2b;
The pillar 2 is composed of the upper pillar member 2a, the lower pillar member 2b, and the pillar body 2c,
The lower end of the upper column member 2a is joined to the upper end of the column body 2c, and the upper end of the lower column member 2b is joined to the lower end of the column body 2c ,
The upper unit 10 and the lower unit 11 are opposed to each other by abutting the upper column member 2a and the lower column member 2b, and the column main body 2c and the building construction are arranged between the upper unit 10 and the lower unit 11. characterized that you accommodating member required.

According to invention of Claim 1 , the building unit 1 is provided with the upper unit 10, the lower unit 11, and the column main body 2c, The lower end part of the said upper column member 2a is joined to the upper end part of the said column main body 2c, Since the upper end of the lower column member 2b is joined to the lower end of the column main body 2c, the length of at least one of the column main body 2c, the upper column member 2a, and the lower column member 2b is increased. Thus, the height of the building unit 1 can be increased.
Further, the column main body 2c can be removed from the upper column member 2a and the lower column member 2b, and the upper unit 10 and the lower unit 11 can face each other by abutting the upper column member 2a and the lower column member 2b. Since the removed column main body 2c and other members necessary for building construction can be stored between the upper unit 10 and the lower unit 11, the upper unit 10, the lower unit 11 and the column main body 2c can be stored in this state. In addition, by transporting other members necessary for building construction, the height during transportation is reduced, thereby improving transportation efficiency.
Then, the upper unit 10 and the lower unit 11 are faced to each other by abutting the upper column member 2a and the lower column member 2b, so that the height during transportation is reduced, and the upper unit 10 and the lower unit 11 are reduced. Since the members necessary for the column main body 2c and building construction are accommodated between the two, the transportation efficiency is improved.

According to a second aspect of the invention, for example, as shown in FIG. 6 (a), (b) , in the process of transporting building unit 1 according to claim 1,
The upper column member 2a and the lower column member 2b have different lengths.

According to the second aspect of the present invention, as shown in FIG. 6A, when the upper column member 2a is longer, the lower unit 11 is lower than the upper unit 10, so the upper unit 10 and the lower unit 11 Before the upper column member 2a and the lower column member 2b face each other and face each other, the column main body 2c and other members necessary for building construction can be easily accommodated in the lower unit 11.
On the other hand, as shown in FIG. 6B, when the lower column member 2b is longer, the upper unit 10 is lower than the lower unit 11 and its weight is reduced. Therefore, the operation for lifting the upper unit 10 is performed. Therefore, the upper unit 10 can be faced to the lower unit 11 by making the upper column member 2a and the lower column member 2b abut each other.

The invention according to claim 3 is the transportation method of the building unit according to claim 1 or 2 , as shown in FIG.
If the reference dimension is h,
The protruding length of the upper column member 2a from the upper frame 12 is n ₁ times h (where n ₁ is an integer),
The protruding length of the lower column member 2b from the lower frame 13 is n ₂ times h (where n ₂ is an integer),
The length of the column body 2c is n times h (where n is an integer greater than n1 and n2).

According to the third aspect of the present invention, the upper column member 2a can be easily manufactured by cutting the manufactured column main body 2c by the size of n ₁ h, and the manufactured column main body 2c can be converted into n _2. The lower column member 2b can be easily manufactured by cutting the dimension h. Therefore, the upper column member 2a and the lower column member 2b can be easily manufactured from the column main body 2c.
Further, it is possible to manufacture a long column main body 2c having a length defined by nh and cut out the column main body 2c having a desired length, the upper column member 2a, and the lower column member 2b from the column main body 2c.
Therefore, the building unit 1 having a desired floor height can be assembled according to the needs of the site.

Invention of Claim 4 is the transport method of the building unit 1 as described in any one of Claims 1-3 , for example, as shown in FIG.
The width L1 of the unit structure 70 formed by facing the upper unit 10 and the lower unit 11 with the upper column member 2a and the lower column member 2b facing each other is an inner method of the width of the transport container 71. Slightly shorter than the dimension K1, and the height dimension L2 of the unit structure 70 is slightly shorter than an integral fraction of the internal dimension K2 of the height of the transport container 71,
One unit structure 70 is stacked on the transport container 71 on the left and right, two or more on the top and bottom, and one or more on the front and back are stacked and transported.

According to the fourth aspect of the present invention, since the plurality of unit components 70 can be loaded and transported in the transport container 71 almost without any gap, transport efficiency and transport cost can be greatly reduced.

According to the present invention, a building unit and an upper unit and a lower part unit and the pillar main body, the lower end of the upper column member is joined to the upper end of the column body, the upper end portion of the lower pillar members to the lower end of the column body Therefore, the height of the building unit can be increased by increasing the length of at least one of the column main body, the upper column member, and the lower column member .
Further, by removing the pillar body from top post member and a lower pillar members, the upper unit and the lower unit, against the upper column member and the lower column member, we are Rukoto opposed to each other, the upper unit and the lower between the units, it is possible to house the members necessary to remove pillars body and other building construction, to transport the upper unit, the lower unit and the pillar main body and other members necessary for building architecture in this state As a result, the height during transportation is reduced, and thus the transportation efficiency is improved.
Then, the upper unit and the lower unit are faced to each other by abutting the upper column member and the lower column member, so that the height during transportation is reduced, and the column is placed between the upper unit and the lower unit. Since the main body and the members necessary for building construction are stored, the transportation efficiency is improved.

1 is a perspective view showing a first embodiment of a building unit according to the present invention. FIG. 6 is a perspective view showing an upper unit and a lower unit during transportation. It is a side view which shows an example of the joining state of a column main body and an upper column member or a lower column member. It is a side view which shows the other example of the joining state of a column main body and an upper column member or a lower column member. It is a front view which shows an example of the upper unit and the lower unit at the time of transport. FIG. 6 is a front view showing another example of the upper unit and the lower unit during transportation. The process which constructs a unit type building with a building unit is shown, and is a process figure which shows from the basic construction to the installation process of the building unit on the first floor. FIG. 5 is a process diagram showing a process of constructing a unit type building by a building unit, from a process of installing a capital plate to a building unit on the first floor to a process of installing a unit on the second floor. FIG. 6 is a process diagram showing a process of constructing a unit type building by a building unit, from a process of installing a capital plate to a building unit on the second floor to a process of installing a cabin panel. It is a perspective view which shows the state which has similarly installed the building unit. It is a perspective view which shows the principal part of a foundation and the lower end part of the pillar of a building unit. It is a perspective view which shows the lower end part of a pillar of a building unit, and an anchor bolt. It is a perspective view which shows the lower end part of the pillar of the building unit in a transportation state. It is a disassembled perspective view which shows the connection structure of the pillars of a building unit. It is a perspective view which shows the building unit which comprises the entrance part same as the above. The 2nd Embodiment of the building unit which concerns on this invention is shown, and it is the perspective view. FIG. 6 is a perspective view showing an upper unit and a lower unit during transportation. It is a front view which shows an example of the upper unit and the lower unit at the time of transport. FIG. 6 is a front view showing another example of the upper unit and the lower unit during transportation. The 3rd Embodiment of the building unit which concerns on this invention is shown, and it is the perspective view. It is a figure for demonstrating the length of an upper column member, a lower column member, and a column main body. It is sectional drawing for demonstrating the method to join a pillar main body to a lower pillar member equally. It is a perspective view which shows the state which removed the pillar main body from the building unit. FIG. 5A is a perspective view showing a unit structure, and FIG. 5B is a cross-sectional view showing a joint portion between an upper column member and a lower column member. It is a perspective view which shows the method to attach a column main body to a unit structure. It is a front view which shows the state which loaded the unit structure on the transport unit. It is a side view which shows the state which loaded the unit structure in the transport unit same as the above. The 4th Embodiment of the building unit which concerns on this invention is shown, and it is a front view which shows the state which loaded the unit structure in the transport unit. It is a side view which shows the state which loaded the unit structure in the transport unit same as the above. The 4th Embodiment of the building unit which concerns on this invention is shown, and it is the perspective view. It is sectional drawing for demonstrating the method to join a column to the corner | angular part of a lower frame. It is a perspective view which shows the state which connected the upper unit and the lower unit with the transportation jig.

Embodiments of the present invention will be described below with reference to the drawings.
(First embodiment)
1 to 15 show a first embodiment of a building unit according to the present invention.
FIG. 1 is a perspective view showing a building unit 1 according to the present embodiment. The building unit 1 includes four columns 2, four ceiling beams 3 that connect the upper ends of these columns 2, and four floor beams 4 that connect the lower ends of the columns 2. .
The four ceiling beams 3 are constituted by two long side ceiling beams 3a and two short side ceiling beams 3b shorter than the long side ceiling beams 3a. The four floor beams 4 are composed of two long side floor beams 4a and two short side floor beams 4b shorter than the long side floor beams 4a. The column 2 is formed in a square cylinder shape, and the ceiling beam 3 and the floor beam 4 are each formed in a U-shaped cross section.

A plurality of ceiling beams 5 are installed on the two long side ceiling beams 3a, 3a, and the ceiling beam 5 is provided at a predetermined interval in the longitudinal direction of the long side ceiling beams 3a. A ceiling plate 6 is fixed to the lower surface of the ceiling beams 5.
A plurality of joists 7 are installed on the two long side floor beams 4a, 4a, and the joists 7 are provided at predetermined intervals in the longitudinal direction of the long side floor beams 4a. A floor plate 8 is fixed to the upper surface of the joists 7.

The building unit 1 having the above-described configuration includes an upper unit 10, a lower unit 11, and a column main body 2 c provided therebetween.
The upper unit 10 is provided with upper column members 2a projecting downward at four corners of an upper frame 12 in which four ceiling beams 3 are assembled in a rectangular frame shape, and the plurality of ceiling small members The beam 5 and the ceiling plate 6 are provided. The upper column member 2 a and the ceiling beam 3 are joined by a stigma joining member 25.
The lower unit 11 is provided with lower pillar members 2b projecting upward at the four corners of the lower frame 13 obtained by assembling the floor beam 4 into a rectangular frame shape. Further, the plurality of joists 7 and the floor plate 8 are provided. It is the composition provided with. The lower column member 2b and the floor beam 4 are joined by a column base joining member 26.

A column main body 2c is provided between the upper column member 2a of the upper unit 10 and the lower column member 2b of the lower unit 11, and the lower end portion of the upper column member 2a is joined to the upper end portion of the column main body 2c. The upper end portion of the lower column member 2b is joined to the lower end portion of the column main body 2c.
The upper column member 2a and the lower column member 2b have the same length, and the column main body 2c is longer than the upper column member 2a and the lower column member 2b. The upper column member 2a, the lower column member 2b, and the column main body 2c are formed in the same cross section, and the upper column member 2a, the lower column member 2b, and the column main body 2c constitute the column 2.

The upper end portion of the lower column member 2b and the lower end portion of the column main body 2c are joined as follows. That is, as shown in FIG. 4, the joining plate 14a is fixed to the upper end surface of the lower column member 2b, and the joining plate 14b is fixed to the lower end surface of the column body 2c. The joining plates 14a and 14b are in contact with each other. The joining plates 14a and 14b are inserted into the joining bolts 15 and screwed into the nuts 16, and then the joining bolts 15 are tightened. Are detachably connected.
In addition, operation holes 17 and 17 are respectively formed in one side wall of the lower column member 2b and the column main body 2c, and a connection bolt 15 such as a high-strength bolt and a nut 16 are inserted into the operation holes 17 and 17. A tool such as a wrench is engaged with the connecting bolt 15 from the operation hole 17 and the connecting bolt 15 is tightened. Thus, by joining the joining plates 14a and 14b, the upper end portion of the lower column member 2b and the lower end portion of the column main body 2c are detachably joined.
Also, the lower end portion of the upper column member 2a and the upper end portion of the column main body 2c are joined in a detachable manner in the same manner as described above.

As shown in FIG. 5, the joining of the upper end portion of the lower column member 2b and the lower end portion of the column body 2c and the joining of the lower end portion of the upper column member 2a and the upper end portion of the column body 2c are performed as shown in FIG. 14b abut each other on the opposing side walls of the upper end of the lower column member 2b and the lower end of the column main body 2c, and on the opposing side walls of the lower end of the upper column member 2a and the upper end of the column main body 2c, respectively. The gusset plates 18 and 18 may be brought into contact with each other, and the gusset plates 18 and 18 may be fixed to the side wall by fixing bolts 19 and 19.
Further, the joining of the upper end portion of the lower column member 2b and the lower end portion of the column body 2c and the joining of the lower end portion of the upper column member 2a and the upper end portion of the column body 2c do not depend on the connecting bolt 15 or the fixing bolt 19, You may join by means, such as welding.

The building unit 1 having the above-described configuration is transported to the site or an assembly site near the site by a truck or a transport ship with the column main body 2c removed from the upper unit 10 and the lower unit 11, respectively.
In this case, as shown in FIG. 2 and FIG. 3, the upper unit 10 and the lower unit 11 are installed facing each other with the upper column member 2a and the lower column member 2b facing each other. For example, after the lower unit 11 is installed on a truck bed or a transport room floor of a transport ship so that the lower column member 2b faces upward, the upper unit 10 is connected to the upper column member 2a at the lower part of the lower unit 11. It faces the column unit 2b and faces the lower unit 11.
The upper unit 10 is not detached from the lower unit 11 by fixing the upper and lower ends of the fastening belt 20 to the long side ceiling beam 3a of the upper unit 10 and the long side floor beam 4a of the lower unit 11, respectively. The upper and lower units 10 and 11 are fastened. Instead of or in addition to the fastening belt 20, the joining plate 14 a at the lower end portion of the upper column member 2 a of the upper unit 10 and the joining plate 14 b at the upper end portion of the lower column member 2 b of the lower unit 11 are connected to the connecting bolt. 15 and nut 16 may be used for connection.
In addition, when transporting with a transport ship, the building unit disassembled in the transport container 71 may be loaded and transported.

Further, before connecting the upper unit 10 to the lower unit 11 so as to face each other, as shown in FIG. 3, the four column main bodies 2 c and members necessary for building construction are accommodated in the lower unit 11. As members necessary for building construction, for example, a spacer 21 provided between the pillars 2 and 2 of the building unit 1, a planar member 22 such as a wall member attached to the inner surface of the building unit 1 and a panel with an opening, etc. . Between the column main body 2 c and the planar member 22 and between the planar members 22, 22, a cushioning material 24 is provided for alleviating the impact during transportation.
As described above, after the column main body 2c, the inter-column 21 and the planar member 22 are accommodated in the lower unit 11, the upper unit 10 is coupled as described above. Thus, members necessary for building construction such as the column main body 2c, the inter-columns 21, and the planar member 22 are accommodated between the upper unit 10 and the lower unit 11.

  The upper unit 10 and the lower unit 11 in which the column main body 2c, the intermediary column 21, the planar member 22 and the like are housed are stacked as a set on the truck bed or the transport room floor of the transport ship. It is done. For example, in the case of a truck bed, it was impossible in the past to stack the building units 1 up and down due to height restrictions, but the upper unit 10 and the lower unit 11 are a pair. It becomes possible to stack two pieces up and down.

A pair of the upper unit 10 and the lower unit 11 is transported to the site and then assembled to the building unit 1 at the site or an assembly site near the site.
That is, first, a pair of the upper unit 10 and the lower unit 11 is suspended from the truck bed by a crane on the site or the like. Thereafter, the fastening belt 20 and the connecting bolt 15 that connected the upper unit 10 and the lower unit 11 are removed, and the upper unit 10 is separated from the lower unit 11, and the internal column main body 2c, the intermediate column 21, the planar member 22, and the like. Take out the materials necessary for building the building.

Next, the lower ends of the column main bodies 2c are joined to the upper ends of the four lower column members 2b of the lower unit 11, respectively. As described above, this joining is performed by connecting the joining plate 14b at the upper end portion of the lower column member 2b and the joining plate 14a at the lower end portion of the column body 2c by the connecting bolt 15 and the nut 16.
Next, the lower ends of the four upper column members 2a of the upper unit 10 are joined to the upper ends of the four column main bodies 2c, respectively. As described above, this joining is performed by connecting the joining plate 14b at the upper end portion of the column body 2c and the joining plate 14a at the lower end portion of the upper column member 2a by the connecting bolt 15 and the nut 16. In this way, the framework of the building unit 1 is assembled.
Then, the planar member 22, such as the inter-column 21, the wall material, and the panel with the opening, is attached to the building unit 1 as necessary.
When the frame of the building unit 1 is assembled, after the upper ends of the column main bodies 2c are joined to the lower ends of the four upper column members 2a of the upper unit 10, the four lower columns of the lower unit 10 are joined. You may join the lower end part of the said column main body 2c to the upper end part of the member 2b, respectively.

Next, as shown in FIGS. 7A, 7B and 10, the building unit 1 is suspended from a foundation 30 constructed on the site by a crane and sequentially installed. In this case, the base 30 is formed with a widened portion 30a that is wider than other portions. Therefore, the building unit 1 is installed so that the pillar 2 of the building unit 1 is positioned in the widened portion 30a. Go.
As shown in FIG. 11, a setting plate 31 is fixed on the upper surface of the widened portion 30 a of the foundation 30, and a plurality of positioning pins 32 are erected on the setting plate 31. An anchor bolt hole 33 is formed in the widened portion 30 a of the foundation 30 on the outer peripheral side of the setting plate 31.
On the other hand, a hole 32a is formed in the lower end surface of the pillar 2 of the building unit 1, and an anchor bolt 34 is screwed and protrudes from the lower end surface as shown in FIG.
When the building unit 1 is installed on the foundation 30, the positioning pin 32 is inserted into the hole 32 a formed on the lower end surface of the column 2, and the anchor bolt 34 is anchored on the widened portion 30 a of the foundation 30. The building unit 1 is positioned and fixed to the foundation 30 by inserting into the bolt holes 33 and pouring a grout material such as mortar into the anchor bolt holes 33.

  As shown in FIG. 13, on the lower end surface of the column 2 of the building unit 1, a transportation jig 35 comprising a plate 35a and an installation cone portion 35b provided on the plate 35a is connected to a bolt 36 with a hexagon wrench. It is removably attached by tightening with a tool 37 such as. The transportation jig 35 is attached to the lower surface of the building unit 1 when the building unit 1 is transported, but is removed before the foundation is installed. When the building unit 1 is transported, the installation cone portion 35b engages with an engagement hole provided in the truck bed so that the building unit 1 is stably installed and transported.

When the building unit 1 is installed on the foundation 30, in principle, the adjacent building units 1 and 1 are installed in contact with each other or with a slight gap between them, as shown in FIG. There is a case where one is installed at a predetermined interval.
In such a case, as shown in FIGS. 7C and 7D, the unit floor beam 40 and the unit beam 41 are arranged between the building units 1 and 1 installed at a predetermined interval, and the unit floor beam 40 is disposed. Both end portions of the unit beam 41 are coupled to the opposing floor beams 4, 4, and both end portions of the unit beam 41 are coupled to the opposing ceiling beams 3, 3.

Further, as shown in FIG. 8A, after or after the building unit 1 is installed on the foundation 30, the exterior material 42 is attached to the side surface facing the outside of the building unit 1.
After all the building units 1 are installed on the foundation 30, the stigma plate 43 is attached to the upper end surface of the pillar 2 of the building unit 1, and the reinforcing beam 44 is attached between the adjacent building units 1 and 1.

As shown in FIG. 8A, the stigma plate 43 connects the pillars 2 of the adjacent building units 1 to each other, and in a plan view, the intersection where the ceiling beams 3 of the building unit 1 intersect in a T shape. , Straddling the columns 2 on the upper end surface of the column 2 located at the intersection where the ceiling beams 3 intersect in a cross shape or at the joint where the ceiling beams 3, 3 of the adjacent building units 1, 1 are arranged in a straight line Arranged. Moreover, the shape and size of the stigma plate 43 differ depending on the intersecting part and the joining part.
For example, as shown in FIG. 14, when four pillars 2... Are arranged at an intersection where the ceiling beam 3 of the building unit 1 intersects in a cross shape, the four pillars 2. A stigma plate 43 having such a size as to cover the upper end surface is used.
And when connecting the column heads of the four columns 2..., A guide pin 45 is erected on the upper end surface of each column 2, and the guide pin 45 is inserted into a hole 43 a formed in the column head plate 43. Further, the connecting bolt 46 is inserted into the hole 43b formed in the pillar head plate 43 and the hole 47 formed in the upper end portion of the pillar 2, and the nut 46a is screwed and tightened to tighten the four pillars 2.・ The stigma is connected. The connecting bolt 46 is also inserted into a hole 48 formed in the lower end portion of the column 2 of the building unit 1 constituting the second floor. Thereby, the upper and lower building units 1 and 1 are connected.

Similarly, the pillars 2... Located at the intersection where the ceiling beam 3 of the building unit 1 intersects in a T shape are connected by a square plate-like pillar head plate 43, and the ceiling beams 3, 3 are arranged in a straight line. The columns 2 and 2 located at the joints are connected by a rectangular stigma plate 43.
Further, among the pillars 2 of the building unit 1, a stigma plate 43 is also provided on the upper end surface of the pillar 2 located at the corner of the building (unit building). Are connected at the corners.

As shown in FIG. 8 (a), the reinforcing beam 44 is formed longer than the ceiling beam 3 of the building unit 1, and is inserted between the ceiling beams 3 and 3 that are opposed to each other with a predetermined gap. , Fixed to the head of the pillar 2. In the present embodiment, the reinforcing beam 44 has a length substantially equal to the total length of the short-side ceiling beam 3b and the unit beam 41, and the opposing unit beams 41 and 41 and the opposing short-side ceiling beam 3b. , 3b and fixed to the heads of the three pillars 2.
By providing the reinforcing beam 44 in this way, the short-side ceiling beam 3b and the unit beam 41 are reinforced, so that the column 2 located at the substantially central portion of the reinforcing beam 44 can be extracted, and as a result, in the building A large space can be formed. The column 2 to be extracted is a jig column and is attached to the building unit 1 when the building unit 1 is installed. After the building unit 1 is installed and the reinforcing beam 44 is provided, the jig column is extracted. To do. In the present embodiment, a desired column main body 2c among the four column main bodies 2c of the building unit 1 can be used as a jig column, and the jig column (column main body 2c) includes an upper column member 2a and a lower column. Since it is bolted to the member 2b by the connecting bolt 15, it can be easily pulled out by removing the connecting bolt 15.
Moreover, since such a reinforcing beam 44 can be provided between desired facing ceiling beams 3 and 3, a large space can be formed in a desired position of a building.

Further, as shown in FIG. 15, among the building units 1 installed on the foundation 30, a building unit (entrance unit) 1 </ b> A constituting the entrance portion has transportation jigs 48 a to 48 d attached to the lower end portions thereof. These transportation jigs 48a to 48d are attached to stably transport the entrance unit 1A, and are removed before being installed on the foundation 30 at the site.
The transport jig 48a is a leg portion that stably installs the entrance unit 1A on the truck bed or the floor of the transport room of the transport ship, and 48b to 48d are temporary beams that prevent deformation of the entrance unit 1A. These are removed before the entrance unit 1A is installed on the foundation 30. Moreover, the stud 21 is attached to the entrance unit 1A.
A unit in front of the entrance (building unit) 1B is joined to the entrance unit 1A as necessary and installed on the foundation 30. Transport jigs 48e to 48h are attached to the lower end of the front entrance unit 1B, and the transport jigs 48e to 48h are removed before installing the front entrance unit 1B on the site.
The transport jig 48e is a leg portion that stably installs the front door unit 1B on the truck bed or the floor of the transport room of the transport ship, and 48f to 48h are temporary beams that prevent deformation of the front door unit 1B. Yes, these are removed before installing the front entrance unit 1B on the foundation 30.

As described above, after all the building units 1 are installed on the foundation 30 and the stigma plate 43 and the reinforcing beam 44 are attached, the building units are installed at a predetermined interval as shown in FIG. 8B. A second-floor floor panel 50 is hung by a crane between the upper ends of 1 and 1, and a balcony unit 51 is further installed and connected to the building unit 1 immediately below it as shown in FIG. 8 (c).
The second floor panel 50 is formed by attaching a face material made of plywood or the like to the upper surface of a rectangular frame, and the lower ends of the pillars 2 of the building unit 1 to be installed on the second floor at four corners. A rectangular notch into which the part is inserted is formed.
Also, since the second floor building unit 1 is installed on the building unit 1, the second floor panel 50 need not be installed.

Next, as shown in FIG. 8 (d), the building unit 1 on the second floor is suspended and installed on the building unit 1 on the first floor by a crane. Next, as shown in FIG. The unit beams 41 are arranged between the building units 1 and 1 installed with the two, and both ends of the unit beams 41 are coupled to the opposing ceiling beams 3 and 3, respectively.
In addition, after or after the building unit 1 is installed, the exterior material 42 is attached to the side surface facing the outside of the building unit 1.
When connecting the building unit 1 on the second floor to the building unit 1 on the first floor, as shown in FIG. 14, the connecting bolt 46 is connected to the holes 48, 1, By inserting through a hole 43b formed in the top plate 43 provided on the upper end surface of the column 2 of the building unit 1 on the floor and a hole 47 formed in the upper end portion of the column 2 and screwing and tightening a nut 46a The upper and lower building units 1 and 1 are connected to each other.

Next, as shown in FIG. 9 (a), the stigma plate 43 is placed on the upper end surface of the column 2 of the building unit 1 on the second floor, as in the case of the upper end surface of the column 2 of the building unit 1 on the first floor. At the same time, the reinforcing beam 44 is attached between the adjacent building units 1 and 1 in the same manner as in the case of the building unit 1 on the first floor.
Next, as shown in FIG. 9B, an exterior material 42 is disposed between the pillars 2 and 2 of the building units 1 and 1 that are installed at a predetermined interval and face outward, Install.
Next, as shown in FIG. 9 (c), a hut panel 52 is hung by a crane between the building units 1 and 1 installed at a predetermined interval, and then the hut unit 53 is installed on the second floor building. Installed in the unit 1, connected to the building unit 1, and finally attached a roof panel (not shown) to the hut unit 53, and the construction of the building (unit type building) is completed by spreading roofing material on this roof panel To do.

According to the present embodiment, the building unit 1 includes the upper unit 10, the lower unit 11, and the column main body 2c, and the lower end portion of the upper column member 2a of the upper unit 10 is joined to the upper end portion of the column main body 2c. Since the upper end of the lower column member 2b of the lower unit 11 is joined to the lower end of the main body 2c, the length of at least one of the column main body 2c, the upper column member 2a, and the lower column member 2b is increased. Thus, the height of the building unit can be increased.
Further, when the building unit 1 is transported by a truck or a transport ship, the upper unit 10 and the lower unit 11 face each other with the upper column member 2a and the lower column member 2b facing each other, so In addition, since the column main body 2c and members necessary for building construction are accommodated between the upper unit 10 and the lower unit 11, the transportation efficiency is improved.

Further, when the building unit 1 is transported, the upper and lower ends of the fastening belt 20 are fixed to the long-side ceiling beam 3a of the upper unit 10 and the long-side floor beam 4a of the lower unit 11, respectively. Since the upper and lower units 10 and 11 are fastened so that the unit 10 does not come off, the building unit 1 can be transported stably.
Further, instead of or in addition to the fastening belt 20, the joining plate 14 a at the lower end portion of the upper column member 2 a of the upper unit 10 and the joining plate 14 b at the upper end portion of the lower column member 2 b of the lower unit 11 are connected to the connecting bolt. By connecting 15 and the nut 16, the building unit 1 can be transported more stably.

In the present embodiment, the upper column member 2a of the upper unit 10 and the lower column member 2b of the lower unit 11 have the same length, but the upper column member 2a and the lower column member 2b have different lengths. Also good.
For example, as shown in FIG. 6A, when the upper column member 2a is longer, the lower unit 11 is lower than the upper unit 10, so that the upper unit 10 and the lower unit 11 are connected to the upper column member 2a and the lower unit. The column main body 2c and other members necessary for building construction can be easily accommodated in the lower unit 11 before they face each other and face each other.
Further, as shown in FIG. 6B, when the lower column member 2b is longer, the upper unit 10 is lower than the lower unit 11, and the weight is reduced. Therefore, when the upper unit 10 is lifted The operability is improved, so that the upper unit 10 and the lower column member 2b can be abutted against the lower unit 11 and easily face each other.

(Second Embodiment)
16 to 19 show a second embodiment of a building unit according to the present invention.
FIG. 16 is a perspective view showing the building unit 1 according to the present embodiment. As with the building unit 1 of the first embodiment, the building unit 1 includes four columns 2, four ceiling beams 3 that connect the upper ends of these columns 2, and the lower ends of the columns 2. Are provided with four floor beams 4. The four ceiling beams 3 are constituted by two long side ceiling beams 3a and two short side ceiling beams 3b shorter than the long side ceiling beams 3a. The four floor beams 4 are composed of two long side floor beams 4a and two short side floor beams 4b shorter than the long side floor beams 4a.

A plurality of ceiling beams 5 are installed on the two long side ceiling beams 3a, 3a, and the ceiling beam 5 is provided at a predetermined interval in the longitudinal direction of the long side ceiling beams 3a. A ceiling plate 6 is fixed to the lower surface of the ceiling beams 5.
A plurality of joists 7 are installed on the two long side floor beams 4a, 4a, and the joists 7 are provided at predetermined intervals in the longitudinal direction of the long side floor beams 4a. A floor board 68 is fixed to the upper surface of the joists 7.

The building unit 1 having the above configuration is composed of an upper unit 60 and a lower unit 61.
The upper unit 60 is provided with upper column members 62a projecting downward at the four corners of the upper frame body 12 in which the four ceiling beams 3 are assembled into a rectangular frame shape. The beam 5 and the ceiling plate 6 are provided.
The lower unit 11 is provided with lower pillar members 62b projecting upward at the four corners of the lower frame 13 obtained by assembling the floor beam 4 into a rectangular frame shape. Further, the plurality of joists 7 and the floor plate 8 are provided. It is the composition provided with.
The upper column member 62a and the lower column member 62b have the same length and are formed in the same cross section, and the upper column member 62a and the lower column member 62b constitute the column 2.

  The upper unit 60 and the lower unit 61 are configured such that the upper column member 62a and the lower column member 62b face each other and face each other, and the lower end portion of the upper column member 62a and the upper end portion of the lower column member 62b are joined. As a result, the framework of the building unit 1 is configured.

The upper end portion of the lower column member 62b and the lower end portion of the upper column member 62a are bonded in the same manner as the upper end portion of the lower column member 2b and the lower end portion of the column main body 2c in the first embodiment. ing.
That is, the joining plate 14a fixed to the lower end surface of the upper column member 62a and the joining plate 14b fixed to the upper end surface of the lower column member 62b are brought into contact with each other, and the connecting bolt 15 is inserted into the joining plates 14a and 14b. The joint plates 14a and 14b are detachably coupled by tightening the coupling bolt 15 such as a high-strength bolt after being screwed into the nut 16 and thereby the upper end portion of the lower column member 62b and the upper column member 62a. The lower end of the slab is detachably joined.

The building unit 1 having the above-described configuration is transported to the site or an assembly site near the site by a truck or a transport ship with the upper unit 60 and the lower unit 61 separated.
In this case, as shown in FIGS. 17 and 18, the upper unit 60 and the lower unit 61 are arranged such that the upper column member 62a and the lower column member 62b overlap in the horizontal direction, and the ceiling beam 3 and the floor beam 4 face each other. Install them so that they face each other.
For example, after the lower unit 61 is installed on the truck bed or the floor of the transport room of the transport ship so that the lower column member 62b faces upward, the upper unit 60 is placed in the horizontal direction (the longitudinal direction of the short-side ceiling beam 3b). The upper column member 62a provided on one end side (left side in FIG. 18) of the short side ceiling beam 3b and the upper column member 62a provided on the other end side (right side in FIG. 18) Are substantially in contact with the side surfaces facing the outside of the lower column member 62b provided on one end side of the short-side floor beam 4b of the lower unit 61, respectively, and inside the lower column member 62b provided on the other end side The upper unit 60 and the lower unit 61 are installed so as to face each other so that they substantially abut on the side surfaces facing the front side.

Furthermore, the upper column member 62a provided on the other end side (the right side in FIG. 18) of the short-side ceiling beam 3b of the upper unit 60 is applied to the short-side floor beam 4b of the lower unit 61 via the buffer material 63. The lower column member 62b provided on one end side of the short side floor beam 4b of the lower unit 61 is in contact with the short side ceiling beam 3b of the upper unit 60 via the cushioning material 63 so that the upper unit 60 and the lower unit 61 are installed facing each other.
And between the upper unit 60 and the lower unit 61, a member required for building construction, such as a stud and the planar member 22, is accommodated. Further, as shown in FIG. 19, the bus unit 64 can be accommodated between the other upper unit 60 and the lower unit 61.

When a member necessary for building construction is stored between the upper unit 60 and the lower unit 61, before installing the upper unit 60 in the lower unit 61 so as to face each other, A member necessary for building construction such as the shaped member 22 and the bus unit 64 are accommodated. Between the planar members 22 and 22, a cushioning material 24 is interposed for mitigating impact during transportation.
As described above, after the studs, the planar member 22, the bus unit 64, and the like are stored in the lower unit 61, the upper unit 60 is installed facing each other as described above. Thus, members necessary for building construction, the bus unit 64, and the like are accommodated between the upper unit 60 and the lower unit 61.

Then, the upper unit 60 and the lower unit 61 in which members necessary for building construction are housed are combined as a set and stacked on the truck bed or the floor of the transport room of the transport ship. For example, in the case of a truck bed, it has been impossible in the past to stack the building units 1 up and down due to height restrictions, but the upper unit 60 and the lower unit 61 are a pair. It becomes possible to stack two pieces up and down.
A pair of the upper unit 60 and the lower unit 61 is transported to the site by a truck or the like and then assembled to the building unit 1 at the site or an assembly site near the site.
That is, first, a pair of the upper unit 60 and the lower unit 61 is suspended from a truck bed or the like by a crane or the like on the site. Thereafter, the upper unit 60 is removed from the lower unit 61, and members necessary for building construction, such as internal pillars and planar members 22, and the bus unit 64 are taken out.

Next, the lower ends of the four upper column members 62 a of the upper unit 60 are joined to the upper ends of the four lower column members 62 b of the lower unit 61. As described above, this joining is performed by connecting the joining plate 14b at the upper end of the lower pillar member 62b and the joining plate 14b at the lower end of the upper pillar member 62a by the connecting bolt 15 and the nut 16. In this way, the framework of the building unit 1 is assembled.
Then, after attaching the studs and the planar member 22 to the building unit 1 as necessary, the completed building unit 1 is connected to the foundation in the same manner as in the first embodiment, Build a building (unit building).

According to the present embodiment, the building unit 1 includes the upper unit 60 and the lower unit 61, and the lower end portion of the upper column member 62a of the upper unit 60 and the upper end portion of the lower column member 62b of the lower unit 61 are joined. Therefore, the height of the building unit 1 can be increased by increasing the length of at least one of the upper column member 62a and the lower column member 62b.
Further, when the building unit 1 is disassembled and transported, the upper unit 60 and the lower unit 61, the upper column member 62a and the lower column member 62b overlap in the horizontal direction, and the ceiling beam 3 and the floor beam 4 face each other. Thus, by facing each other, the height at the time of transportation is reduced, and the members and the bus unit 64 necessary for building construction are accommodated between the upper unit 60 and the lower unit 61. Efficiency is improved.

In the present embodiment, when the upper unit 60 and the lower unit 61 are installed facing each other so that the upper column member 62a and the lower column member 62b overlap in the horizontal direction, the upper unit 60 is shortened. Although it shifted to the longitudinal direction of the side ceiling beam 3b, it replaces with this and you may shift the upper unit 60 to the longitudinal direction of the long side ceiling beam 3a.
Further, in the present embodiment, the upper unit 60 and the lower unit 61 are faced to each other so that the upper column member 62a and the lower column member 62b overlap in the horizontal direction. The member 62a and the lower column member 62b may face each other so as to overlap each other. That is, the state shown in FIG. 18 may be rotated 90 degrees. In this case, the upper unit 60 and the lower unit 61 may be fastened with a fastening belt (not shown) so that they are not separated from each other. Further, instead of or in addition to the fastening belt, the lower end portion of the upper column member 62a is connected to the floor beam 4 of the lower unit 61 by the connecting bolt 15, and the upper end portion of the lower column member 62b is connected to the ceiling of the upper unit 60. The beam 3 may be connected by the connecting bolt 15.

(Third embodiment)
20 to 27 show a third embodiment of a building unit according to the present invention.
As shown in FIG. 20, the building unit 1 of the present embodiment combines four columns 2, four ceiling beams 3 that couple the upper ends of these columns 2, and the lower ends of the columns 2. The four floor beams 4 are provided.
The four columns 2, the four ceiling beams 3, and the floor beam 4 are joined by a column head joining member 25 and a column leg joining member 26, respectively. The column head joint member 25 is fixed to the upper end of the column 2, and the two ceiling beams 3 and 3 are joined to the column head joint member 25. The column base joining member 26 is fixed to the lower end portion of the column 2, and the two floor beams 4 and 4 are joined to the column base joining member 26.
The four ceiling beams 3 are constituted by two long side ceiling beams 3a and two short side ceiling beams 3b shorter than the long side ceiling beams 3a. The four floor beams 4 are composed of two long side floor beams 4a and two short side floor beams 4b shorter than the long side floor beams 4a. The column 2 is formed in a square cylinder shape, and the ceiling beam 3 and the floor beam 4 are each formed in a U-shaped cross section.

A plurality of ceiling beams 5 are installed on the two long side ceiling beams 3a, 3a, and the ceiling beam 5 is provided at a predetermined interval in the longitudinal direction of the long side ceiling beams 3a. A ceiling plate (not shown) is fixed to the lower surface of these ceiling beams 5.
A plurality of joists 7 are installed on the two long side floor beams 4a, 4a, and the joists 7 are provided at predetermined intervals in the longitudinal direction of the long side floor beams 4a. A floor board (not shown) is fixed to the upper surface of the joists 7.

The building unit 1 having the above-described configuration includes an upper unit 10, a lower unit 11, and a column main body 2 c provided therebetween.
The upper unit 10 is provided with upper column members 2a protruding downward respectively at the stigma joining members 25 at the four corners of the upper frame 12 in which the four ceiling beams 3 are assembled in a rectangular frame shape. The plurality of ceiling beams 5 and a ceiling plate are provided.
The lower unit 11 is provided with lower column members 2b projecting upward from the leg joint members 26 at the four corners of the lower frame 13 obtained by assembling the floor beam 4 into a rectangular frame shape. It has a configuration including a plurality of joists 7 and a floor board.

A column main body 2c is provided between the upper column member 2a of the upper unit 10 and the lower column member 2b of the lower unit 11, and the lower end portion of the upper column member 2a is joined to the upper end portion of the column main body 2c. The upper end portion of the lower column member 2b is joined to the lower end portion of the column main body 2c.
The upper column member 2a and the lower column member 2b have the same length, and the column main body 2c is longer than the upper column member 2a and the lower column member 2b. The upper column member 2a, the lower column member 2b, and the column main body 2c are formed in the same cross section, and the upper column member 2a, the lower column member 2b, and the column main body 2c constitute the column 2.

Here, the lengths of the upper column member 2a, the lower column member 2b, and the column body 2c are set as follows.
That is, as shown in FIG. 21, when the reference dimension is h, the protruding length of the upper column member 2a from the stigma joining member 25 of the upper frame 12 is n ₁ times h (where n ₁ is an integer). It has become.
Further, the protruding length of the lower frame member 13 of the lower column member 2b from the column leg joining member 26 is n ₂ times h (where n ₂ is an integer).
Furthermore, the length of the column body 2c is n times h (where n is an integer greater than n ₁ and n ₂ ). In the present embodiment, n ₁ = n ₂ .

The upper end portion of the lower column member 2b and the lower end portion of the column main body 2c are joined as follows. That is, as shown in FIG. 22, a square cylindrical backing metal 27 is inserted and fixed at the upper end of the lower column member 2b with its upper half protruding from the upper end of the lower column member 2b. On the other hand, a rectangular ring-shaped stopper 28 is inserted and fixed inside the lower end portion of the column main body 2c in a state of being retracted by a predetermined length from the lower end of the column main body 2c.
And the upper end part of the lower column member 2b and the lower end part of the column main body 2c are such that the backing metal 27 protruding from the upper end of the lower column member 2b is inside the lower end part of the column main body 2c. After being inserted until it comes into contact with the stopper 28, the upper end of the lower column member 2b and the lower end of the column body 2c are joined together by welding.
When the backing metal 27 is inserted into the lower end portion of the column main body 2c until it comes into contact with the stopper 28, a predetermined gap is formed between the lower end of the column main body 2c and the lower column member 2b. Therefore, welding is performed using this gap.

Moreover, when joining the upper end part of the column main body 2c, and the upper column member 2a, it carries out similarly to the above. That is, a square cylindrical backing metal 27 is inserted and fixed at the upper end of the column main body 2c with its upper half protruding from the upper end of the column main body 2c, while a stopper is provided inside the lower end of the upper column member 2a. 28 is inserted and fixed in a state of being retracted by a predetermined length from the lower end of the upper column member 2a, and a backing metal 27 protruding from the upper end of the column body 2a is placed inside the lower end of the upper column member 2a. After the gold 27 is inserted until it comes into contact with the stopper 28, the upper end of the column main body 2c and the lower end of the upper column member 2a are joined together by welding.
The building unit 1 as described above, for example, is loaded in a transport container and transported by the transport ship. Before the assembly at the site, welding as described above is not performed, and the building unit 1 at the site after transport. Welding when assembling.
As shown in FIG. 20, a hook 29 used when the building unit 1 (unit component 70) is pulled out from a shipping container described later is screwed into the leg joint member 26 of the lower unit 11 of the building unit 1. Attached.

When loading the unit 1 into the transport container, as shown in FIG. 23, after removing the column main body 2c from the building unit 1, as shown in FIG. 24, the upper end of the lower column member 2b of the lower unit 11 and the upper unit 10 are removed. The unit structure 70 is configured by abutting and joining the upper end of the upper column member 2b. This joining is performed by inserting the backing metal 27 protruding from the upper end of the lower column member 2 b into the lower end portion of the upper column member 2 a until the backing metal 27 comes into contact with the stopper 28.
Thereafter, the upper unit 10 is detached from the lower unit 11 by fixing upper and lower ends of the fastening belt (not shown) to the long side ceiling beam 3a of the upper unit 10 and the long side floor beam 4a of the lower unit 11, respectively. The upper and lower units 10 and 11 are fastened so that there is no.
Further, before connecting the upper unit 10 to the lower unit 11 so as to face each other, as shown in FIG. 26, the column main body 2c and members necessary for building construction are accommodated in the lower unit 11. The column main body 2c stores, for example, a plurality of types having different lengths. As members necessary for building construction, for example, a spacer 21 provided between the pillars 2 and 2 of the building unit 1, a planar member 22 such as a wall member attached to the inner surface of the building unit 1, a panel with an opening, and the like are included. . Between the column main body 2 c and the planar member 22 and between the planar members 22, 22, a cushioning material 24 is provided for alleviating the impact during transportation.

As described above, after the column main body 2c, the inter-column 21 and the planar member 22 are accommodated in the lower unit 11, the upper unit 10 is coupled as described above. Thereby, members necessary for building construction such as the column main body 2 c, the intermediate column 21, and the planar member 22 are accommodated between the upper unit 10 and the lower unit 11, that is, in the unit structure 70.
Further, belt-like sliding materials 72 and 72 are attached to both sides of the lower surface of the lower unit 11. Therefore, when the two-stage unit structures 70, 70 are stacked in the transport container 71 in the vertical direction, a gap corresponding to the thickness of the sliding material 72 is provided between the unit structures 70, 70. Further, a gap is provided between the bottom in the transport container 71 and the unit structure 70 by the thickness of the sliding material 72.

As shown in FIG. 26, when the unit structure 70 is loaded into a transport container 71 and transported, the dimensions of the upper unit 10 and the lower unit 11, that is, the dimensions of the unit structure 70 are matched to the transport container 71. Is set.
That is, first, the width dimension L1 of the unit structure 70 formed by abutting the upper unit 10 and the lower unit 11 with the upper column member 2a and the lower column member 2b facing each other is an inner method of the width of the transport container 71. It is set slightly shorter than the dimension K1.
In addition, the height dimension L2 of the unit structure 70 is set to be slightly shorter than 1 / integer of the internal dimension K2 of the height of the transport container 71. For example, the height dimension L2 of the unit structure 70 is set slightly shorter than one half of the internal dimension K2 of the height of the transport container 71.
Furthermore, as shown in FIG. 27, the length dimension L3 of the unit structure 70 is set to be slightly shorter than 1 / integer of the internal dimension K3 of the length of the transport container 71. For example, the length dimension L3 of the unit structure 70 is set to be slightly shorter than 1/1 of the internal dimension K3 of the length of the transport container 71.
And in this Embodiment, the unit structure 70 is piled up and transported to the transport container 71 by stacking one unit on the left and right, two on the top and bottom, and one on the front and back.
As the transport container 71, a 20 ft or 40 ft dry container is used. In a 20 ft dry container, one unit structure 70 can be transported by stacking one unit on the left and right, two on the top and bottom, and one on the front and back, and a total of two units can be transported on a 40 ft dry container. , Two can be stacked on top and bottom, and two can be stacked on the front and back to transport a total of four.

The unit structure 70 as described above is transported to the site by the transport container 71 and then assembled to the building unit 1 at the site or an assembly site near the site.
That is, first, the unit structure 70 is pulled out from the transport container 71. In this case, the hooks of the crane are hooked on the hooks 29 and 29 attached to the unit structure 70 and pulled out. Since the sliding members 72, 72 are provided on the lower surface of the unit structure 70, they can be pulled out relatively smoothly.
After pulling out the unit structure 70 by a predetermined length, hook the crane on the upper part of the unit structure 70 and hang it down, and then remove the fastening belt that connects the upper unit 10 and the lower unit 11. The upper unit 10 is separated from the lower unit 11, and members necessary for building construction such as the internal column main body 2c, the inter-column 21 and the planar member 22 are taken out.

Next, as shown in FIG. 22, the lower ends of the column main bodies 2c are joined to the upper ends of the four lower column members 2b of the lower unit 11, respectively. As described above, the joining is performed by inserting the backing metal 27 protruding from the upper end of the lower column member 2b into the lower end of the column main body 2c until the backing metal 27 comes into contact with the stopper 28. .
Next, the lower ends of the four upper column members 2a of the upper unit 10 are joined to the upper ends of the four column main bodies 2c, respectively. As described above, the joining is performed by inserting the backing metal 27 protruding from the upper end of the column body 2c into the lower end portion of the upper column member 2a until the backing metal 27 comes into contact with the stopper 28. .
And it joins by welding the upper end of the lower column member 2b, the lower end of the column main body 2c, and the upper end of the column main body 2c, and the lower end of the upper column member 2a. In this way, the framework of the building unit 1 is assembled. When joining the column main bodies 2c, as shown in FIG. 25, the column main bodies 2c having different lengths are facilitated as appropriate, and the desired column main bodies 2c are selected. This makes it possible to assemble the building unit 1 having a floor height that meets the needs at the site. The column main bodies 2c having different lengths are appropriately stored in the unit structure 70 and transported.
Then, after attaching the planar member 22, the planar member 22 such as a wall material or a panel with an opening to the building unit 1 as necessary, the completed building unit 1 is made in the same manner as in the first embodiment. A building (unit building) is constructed by connecting to the foundation while connecting.

According to the present embodiment, the protruding length of the upper column member 2a from the upper frame 12 is n ₁ times the reference dimension h (where n ₁ is an integer), and the lower frame of the lower column member 2b. The protrusion length from 13 is n ₂ times h (where n ₂ is an integer), and the length of the column body 2c is n times h (where n is an integer greater than n1 and n2). Therefore, the upper column member 2a can be easily manufactured by cutting the manufactured column main body 2c by the size of n ₁ h, and by cutting the manufactured column main body 2c by the size of n ₂ h, The lower column member 2b can be easily manufactured. Therefore, the upper column member 2a and the lower column member 2b can be easily manufactured from the column main body 2c.
Further, it is possible to manufacture a long column main body 2c having a length defined by nh and cut out the column main body 2c having a desired length, the upper column member 2a, and the lower column member 2b from the column main body 2c. Therefore, the building unit 1 having a desired floor height can be assembled according to the needs of the site.

  Further, the width dimension L1 of the unit structure 70 is slightly shorter than the internal dimension K1 of the width of the transport container 71, and the height dimension L2 of the unit structure 70 is an integer of the internal dimension K2 of the height of the transport container 71. The length L3 of the unit structure 70 is set to be slightly shorter than an integral number of the internal dimension K3 of the length of the transport container 71. Since the components 70 are stacked one by one on the left and right, two or more on the top and bottom, and one or more on the front and back are stacked and transported, a plurality of unit components 70 can be loaded and transported in the transport container 71 almost without gaps. Therefore, transportation efficiency and transportation cost can be greatly reduced.

(Fourth embodiment)
FIG. 28 is a diagram showing a state in which the unit structural bodies 75 and 75 shown in FIG. The same components as those of the unit structure 75 shown in FIG. 18 are denoted by the same reference numerals, and the description thereof is omitted or simplified.
The unit structural body 75 is configured so that the upper unit 60 and the lower unit 61 are oriented so that the upper column member 62a and the lower column member 62b overlap in the horizontal direction and the ceiling beam 3 and the floor beam 4 face each other. It is a combination.

The width dimension L1 of the unit structure 75 is set slightly shorter than the internal dimension K1 of the width of the transport container 71.
In addition, the height dimension L2 of the unit structure 75 is set to be slightly shorter than 1 / integer of the internal dimension K2 of the height of the transport container 71. For example, the height dimension L2 of the unit structure 75 is set slightly shorter than one half of the internal dimension K2 of the height of the transport container 71.
Furthermore, as shown in FIG. 29, the length dimension L3 of the unit structure 75 is set to be slightly shorter than 1 / integer of the internal dimension K3 of the length of the transport container 71. For example, the length dimension L3 of the unit structural body 75 is set slightly shorter than one-half of the internal dimension K3 of the length of the transport container 71.
And in this Embodiment, the unit structure 75 is piled up and transported to the transport container 71, one unit on the left and right, two on the top and bottom, and one on the front and back.

  In addition, when the unit structural bodies 75 and 75 are loaded in the transport container 71, strip-like sliding materials 72 and 72 are attached to both sides of the lower surface of the lower unit 61. Therefore, when the two-stage unit structural bodies 75 and 75 are stacked in the transport container 71 in the vertical direction, a gap corresponding to the thickness of the sliding material 72 is provided between the unit structural bodies 75 and 75. Further, a gap corresponding to the thickness of the sliding material 72 is provided between the bottom in the transport container 71 and the unit component 75. A hook 29 used for pulling out the unit structure 75 from the transport container 71 is screwed onto the lower unit 61 of the unit structure 75.

  According to the present embodiment, the width dimension L1 of the unit structure 75 is slightly shorter than the internal dimension K1 of the width of the transport container 71, and the height dimension L2 of the unit structure 75 is equal to the height of the transport container 71. The length L3 of the unit component 75 is set slightly shorter than an integer of the inner dimension K3 of the length of the transport container 71. In the transport container 71, one unit structure 75 is stacked on the left and right, two or more on the top and bottom, and one or more units are stacked and transported side by side. It can be loaded and transported without any problems, thus greatly reducing transportation efficiency and transportation costs.

(Fifth embodiment)
30 to 32 show a fifth embodiment of a building unit according to the present invention.
As shown in FIG. 30, the building unit 1 according to the present embodiment combines four columns 2, four ceiling beams 3 that connect the upper ends of these columns 2, and the lower ends of the columns 2. The four floor beams 4 are provided.
The four ceiling beams 3 are constituted by two long side ceiling beams 3a and two short side ceiling beams 3b shorter than the long side ceiling beams 3a. The side ceiling beam 3b is joined by the stigma joining member 25, and thereby the upper frame body 12 is configured.
The two long side ceiling beams 3a, 3a are provided with a plurality of ceiling small beams 5, and the ceiling small beams 5 are provided at predetermined intervals in the longitudinal direction of the long side ceiling beams 3a. A ceiling plate (not shown) is fixed to the lower surface of these ceiling beams 5. Thus, the upper unit 10 is configured.
The four floor beams 4 are composed of two long side floor beams 4a and two short side floor beams 4b shorter than the long side floor beam 4a. The floor beam 4b is joined by a column base joining member 26, and thereby the lower frame 13 is configured.
A plurality of joists 7 are installed on the two long side floor beams 4a, 4a, and the joists 7 are provided at predetermined intervals in the longitudinal direction of the long side floor beams 4a. A floor board (not shown) is fixed to the upper surface of the joists 7. Thus, the lower unit 11 is configured.
The column 2 is formed in a square cylinder shape, and the ceiling beam 3 and the floor beam 4 are each formed in a U-shaped cross section.

Four pillars 2 are provided between the upper unit 10 and the lower unit 11, and a stigma joining member 25 at the corner of the upper frame 12 is joined to the upper end of the pillar 2, and the lower end of the pillar 2. The column base joining members 26 at the corners of the lower frame 13 are joined to each other.
The lower end portion of the column 2 and the column base joining member 26 at the corner portion of the lower frame 13 are joined as follows.
That is, as shown in FIG. 31, a square cylindrical backing metal 27 is fixed to the upper surface of the column base joining member 26 by welding or the like. On the other hand, a rectangular ring-shaped stopper 28 is inserted and fixed inside the lower end portion of the column 2 while being retracted by a predetermined length from the lower end of the column 2.
The upper surface of the column base joining member 26 and the lower end portion of the column 2 are such that the backing metal 27 protruding from the upper surface of the column base joining member 26 is inside the lower end portion of the column 2 and the backing metal 27 is a stopper. After being inserted until it comes into contact with 28, the upper surface of the column base joint member 26 and the lower end of the column 2 are joined together by welding.
When the backing metal 27 is inserted into the lower end portion of the column 2 until it contacts the stopper 28, a predetermined gap is formed between the lower end of the column 2 and the upper surface of the column base joining member 26. Welding is performed using this gap.

  Similarly, the upper end of the pillar 2 and the stigma joining member 25 at the corner of the upper frame 12 are joined. In other words, the lower surface of the columnar joint member 25 and the upper end portion of the column 2 are such that the backing metal 27 protruding from the lower surface of the columnar joint member 25 is inside the upper end portion of the column 2 and the backing metal 27 is the stopper 28. After being inserted until they abut, they are joined by welding the lower surface of the stigma joining member 25 and the upper end of the pillar 2.

The building unit 1 as described above is disassembled into an upper unit 10, a lower unit 11, and a pillar 2. For example, the building unit 1 is loaded into a transport container and transported by the transport ship. The building unit 1 is assembled at the site after transport without any welding.
When the unit 1 is loaded into the transport container, as shown in FIG. 32, a cylindrical column-shaped transport jig 80 shorter than the column 2 is provided between the columnar joint member 25 of the upper unit 10 and the column base joint member 26 of the lower unit 11. , And the upper end portion of the transport jig 80 is joined to the stigma joining member 25 and the lower end portion is joined to the pedestal joining member 26. This joining is performed by inserting the backing metal 27 projecting from the lower surface of the stigma joining member 25 and the lower surface of the pedestal joining member 26 into the upper and lower ends of the transport jig 80, respectively.
Thereafter, the upper unit 10 is detached from the lower unit 11 by fixing upper and lower ends of the fastening belt (not shown) to the long side ceiling beam 3a of the upper unit 10 and the long side floor beam 4a of the lower unit 11, respectively. The upper and lower units 10 and 11 are fastened so that there is no.
In addition, before the upper unit 10 is connected to the lower unit 11 so as to face each other and the transport jig 80 is sandwiched therebetween, the pillar 2 and other members necessary for building construction are accommodated in the lower unit 11.

As described above, after the pillar 2 and other members are accommodated in the lower unit 11, the upper unit 10 is coupled as described above. Thereby, the pillar 2 and other members are accommodated between the upper unit 10 and the lower unit 11.
The disassembled building unit 1 as described above is transported to the site by a shipping container, and then assembled to the building unit at the site or an assembly site near the site.
That is, first, the hooks of the crane are hooked on the hooks 29 and 29 attached to the lower unit 11 and pulled out. After pulling out a predetermined length, a crane hook is hooked on the upper unit 10 and suspended, and then the fastening belt connecting the upper unit 10 and the lower unit 11 is removed, and the upper unit 10 is removed from the lower unit 11. Separate and take out the internal pillar 2 and other members.

Next, after placing the lower unit 11 in a predetermined place, the lower ends of the pillars 2 are joined to the upper surfaces of the column base joining members 26 of the lower unit 11. As described above, this joining is performed by inserting the backing metal 27 protruding from the upper surface of the column base joining member 26 into the lower end portion of the pillar 2 until the backing metal 27 comes into contact with the stopper 28. .
Next, the lower surfaces of the four stigma joining members 25 of the upper unit 10 are joined to the upper ends of the four pillars 2 respectively. As described above, the joining is performed by inserting the backing metal 27 protruding from the lower surface of the stigma joining member 25 into the lower end portion of the pillar 2 until the backing metal 27 comes into contact with the stopper 28.
And it joins by welding the upper surface of the column base joining member 26, the lower end of the column 2, the upper end of the column 2, and the lower surface of the column head joining member 25. In this way, the framework of the building unit 1 is assembled. When joining the columns 2, columns having different lengths are facilitated as appropriate, and the desired columns 2 are selected. This makes it possible to assemble the building unit 1 having a floor height that meets the needs at the site.
Then, after attaching planar members, such as a stud, a wall material, and a panel with an opening part, to the building unit 1 as needed, the completed building unit 1 is made into the foundation like 1st Embodiment. A building (unit building) is constructed by connecting while installing.

According to the present embodiment, the building unit 1 includes the upper unit 10, the lower unit 11, and the column 2 provided between the upper unit 10 and the lower unit 11, and the upper frame 12 is provided at the upper end of the column 2. The column head joint members 25 at the corners of the lower frame 13 are joined to the lower ends of the columns 2, and the column leg joint members 26 at the corners of the lower frame 13 are joined. Therefore, by increasing the length of the columns 2, the building unit The height of 1 can be increased.
In addition, the upper unit 10 and the lower unit 11 are stacked with a predetermined interval through a column-shaped transport jig 80 shorter than the column 2, and the column 2 is placed sideways between the upper unit 10 and the lower unit 11. By storing and transporting the upper unit 10, the lower unit 11, the pillar 2, and other members necessary for building construction in this state, the height at the time of transportation is lowered, and thus the transportation efficiency is improved.

DESCRIPTION OF SYMBOLS 1 Building unit 2 Column 2a, 62a Upper column member 2b, 62b Lower column member 2c Column main body 3 Ceiling beam 4 Floor beam 10,60 Upper unit 11, 61 Lower unit 12 Upper frame 13 Lower frame 70, 75 Unit structure 71 Transport container

Claims (4)

A building that disassembles and transports a building unit that includes a plurality of columns, a plurality of ceiling beams that connect the top ends of these columns, and a plurality of floor beams that connect the bottom ends of the columns. In the unit transportation method ,
The building unit includes an upper unit provided with an upper column member projecting downward at a corner of an upper frame body in which the ceiling beam is assembled into a frame shape;
A lower unit provided with a lower column member projecting upward at a corner of a lower frame assembled in a frame shape with the floor beam;
A column main body provided between the upper column member and the lower column member;
The column is composed of the upper column member, the lower column member, and a column main body,
The lower end of the upper column member is joined to the upper end of the column body, and the upper end of the lower column member is joined to the lower end of the column body ,
The upper unit and the lower unit face each other by abutting the upper column member and the lower column member, and the column main body and members necessary for building construction are stored between the upper unit and the lower unit. A method for transporting a building unit. In the transportation method of the building unit of Claim 1 ,
The method of transporting a building unit , wherein the upper column member and the lower column member have different lengths. In the transportation method of the building unit of Claim 1 or 2 ,
If the reference dimension is h,
The protruding length of the upper column member from the upper frame is n ₁ times h (where n ₁ is an integer),
The protruding length of the lower column member from the lower frame is n ₂ times h (where n ₂ is an integer),
A method for transporting a building unit , wherein the length of the column body is n times h (where n is an integer greater than n1 and n2). In the transportation method of the building unit as described in any one of Claims 1-3 ,
The width dimension of the unit structure formed by abutting the upper unit and the lower unit with the upper column member and the lower column member facing each other is slightly shorter than the inner dimension of the width of the transport container. The height dimension of the structure is slightly shorter than an integral number of the internal dimensions of the height of the transport container;
A method for transporting a building unit, comprising transporting one unit structure on the transport container, one on the left and right, two or more on the top and bottom, and one or more on the front and back.

Images