JPH01146037A - Unit building - Google Patents

Abstract

PURPOSE: To provide a house superior in the workability and the correspondability to the rain of the edge of eaves by loading a roof unit having a horizontal distance longer than a width of a room unit and having a length shorter than the room unit, on the room unit in a state that the lower edges of the room unit project from the ends in the width direction of an upper surface of the room unit. CONSTITUTION: A room unit 13 of which a horizontal distance A1 in the flow direction is longer than a width (w) of the room units 11, 12, and a room length A2 in the direction perpendicular to the flow direction is shorter than the lengths 1, 1' of the room units 11, 12, is loaded on the upper surfaces of the room units 11, 12. The inclined lower ends in the flow direction of the room unit 13 project from the ends in the width direction of the room units 11, 12 to form the edge of eaves 13A, whereby the workability and the correspondability to the rain of the edge of eaves of a house 10 can be improved.

Description

[Detailed description of the invention] [Industrial application field] The present invention relates to unit buildings.

[Conventional technology J As a method to increase the industrial production rate of buildings,
There is a unique building system as described in Japanese Patent No. 54221. In the unit building system, one building is divided into multiple units and each unit is produced in a factory. Units produced in a factory are transported to a construction site and installed on a pre-constructed foundation.

Here, the unique building consists of a room unit having a room space and a roof unit forming a roof part,
It consists of a roof unit mounted on the top of a room unit.

By the way, the room units and roof units constituting a unit building are given widths and lengths that are as large as possible while still being transportable, in consideration of transportation efficiency from the factory to the construction site. In other words, on the top of each room unit,
A corresponding roof double knee/) with a horizontal distance and a roof length of the width and length of the room unit is mounted.

[Problems to be Solved by the Invention] However, in the above-mentioned conventional unit building, since the roof unit is arranged correspondingly to the upper surface of the room unit as described above, it is not possible to form an eaves with the roof unit. Therefore, when forming an eave in a unit building, it is necessary to connect one eave unit to the eave side end of the roof unit.

When using the eaves unit as described above in a unit building, there are the following problems.

■Since the eaves are the part of the roof that is most exposed to the loads of snow, rain, wind, etc., each eaves unit must be firmly connected to the roof unit.

■It is necessary to consider the rainwater at the boundary between the main roof surface formed by the roof unit and the light layer root surface formed by the eaves unit.

Due to (1) and (2) above, the joint structure of the one-house unit becomes complicated, and construction at a construction site away from the factory is difficult and dangerous.

An object of the present invention is to improve the workability and rain protection of the eaves of a unit building by using a roof unit with dimensions that do not impair the transportation efficiency of the units that make up the unit building.

[Means for Solving the Problems] The present invention provides a unit building in which a roof unit is mounted on the upper surface of a room unit, in which the horizontal distance in the flow direction of the roof unit is equal to or smaller than the room unit along the flow direction of the roof unit. The roof length in the direction perpendicular to the flow of the roof unit is set to be larger than the width, and the length of the roof in the direction perpendicular to the flow of the roof unit is set smaller than the length of the room unit along the direction perpendicular to the flow of the roof unit. The eaves protrude from the end in the width direction to form an eaves part.

[Operation] In the present invention, although the horizontal distance of the roof unit in the flow direction is set larger than the width of the room unit, the roof length of the roof unit in the flow direction is set smaller than the length of the room unit.

Therefore, the horizontal distance in the flow direction of the roof unit and the length of the room unit are approximately concave within the maximum transportable dimensions, and the roof length in the direction perpendicular to the wave of the roof unit and the width of the room unit are It can be made substantially concave within the maximum transportable size range. Thereby, the dimensions of each unit can be set to be as large as possible without impairing transportation efficiency.

Further, since the lower end of the roof unit protrudes from the end in the width direction of the upper surface of the room unit to form the eaves, a strong eaves can be formed without joining the eaves to the roof unit. In addition, since the roof unit forms the main roof surface and the light layer root surface continuously over a long range in the direction of flow of rainwater without passing through the boundary, the roof surface's ability to shed rain can be improved. .

Therefore, according to the present invention, by using a roof unit with dimensions that do not impair the transportation efficiency of the units constituting the unit building, the workability for the eaves portion of the unit building is improved.
It is possible to improve rain protection.

[Embodiment] FIG. 1 is a schematic front view showing an embodiment of the present invention, FIG. 2 is a schematic perspective view of FIG. 1, and FIG. 3 is a schematic plan view of FIG. 1.

The unit building IO has three room units 11 and three room units 12 arranged adjacent to each other, and three room units) 11
Six roof units 13 are mounted on the top surface, and four roof units 13 are mounted on the top surface of three room units 12.

In each room (Units) 11 and 12, a frame is assembled in a factory using, for example, lightweight shaped steel, and floors, ceilings, walls, and various equipment are attached to the frame as necessary, and the interior and exterior are finished. At this time, one room unit) 11 has a width W of, for example, 2.5 m and a length of, for example, 5.4 m, and the room unit 12 has @W as a room unit/ ) l l, and the length ' is, for example, 3. .6m.

Each roof unit 13 also has a frame such as a truss structure made of lightweight steel, for example, assembled in a factory, and a roof material is attached to the frame to form a roof surface. Note that the roof unit 13 has a single-sided roof surface that forms the ridge of the building IO.

Here, each roof unit 13 mounted on the upper surface of each room unit 11.12 has a horizontal pressure 111AI in the flow direction of the roof unit 11.
．． The roof length A2 in the direction perpendicular to the flow direction is set to be larger than the width W of the roof unit 12, and smaller than the length A2 of the roof unit 13 in the direction perpendicular to the flow direction of the room units 11 and 12.

In this embodiment, the horizontal distance A1 of the roof unit 13 in the flow direction is approximately equal to the length of the room unit) 11, and the roof length A2 of the roof unit) 13 in the direction perpendicular to the flow is the length of the room unit) 11. The length is set approximately equal to the length (for example, 1.8 m) obtained by dividing the length intersection (for example, 5.4 m) into three.

As a result, each roof unit) 13 has the upper end of the slope in the flow direction located at the center in the width direction of the upper surface of the room unit) 11.12 located in the center of the building, and the lower end of the slope in the flow direction is located on both sides of the building. The eaves portion 13A protrudes from the widthwise end of the upper surface of the room unit 11.

Next, the operation of the above embodiment will be explained.

In the above embodiment, although the horizontal distance A1 of the roof unit 13 in the flow direction is set larger than the width W of the room unit 11.12, the roof length A2 of the roof knee 2) 13 in the flow direction is 11. Look at the length of 12,
It is set smaller than it looks. Therefore, roof units)
The horizontal distance At in the flow direction of the roof unit 13 and the length of the room unit 11 are approximately concave within the maximum transportable dimension, and the roof length A in the flow direction of the roof unit 13 is
2 and room unit) 11.12 4@W can be made approximately concave within the maximum transportable size range. Thereby, the dimensions of each unit 11 to 13 can be set to be as large as possible without impairing transportation efficiency.

Also, the lower end of the roof unit 13 is a room unit)11.
Since the eaves part 13A is formed by protruding from the widthwise end of the upper surface of the roof unit 12, a strong eaves part can be formed without joining the eaves part knees to the roof unit. In addition, since the roof unit 13 forms the main roof surface and the light layer root surface continuously over a long range in the flow direction in which rainwater flows down without passing through the boundary, the rain-shedding performance of the roof surface is improved. can.

Therefore, according to the above-mentioned embodiment, the roof units 13 having dimensions that do not impair the transportation efficiency of the units constituting the unit building 10 are used to improve the workability and rain protection of the eaves of the unit building 10. E can be done.

In addition, as in the above embodiment, ■room unit) 11
Assuming that the widths W of units 11 and 12 are the same, and looking at the lengths of room units 11 and 12, the widths of units 11 and 12 are 5 and 4 m, respectively, which are integral multiples of 1.8 m.
, 3.8m and ■ Roof unit, 13
The roof length A2 along the direction perpendicular to the flow of the room unit) 1
If the length of roof unit 1 is set to 1.8 m, which is obtained by dividing the length of roof unit 1 into three, the same roof unit 13 can be shared by room units 11 and 12 of different sizes and shapes.

[Effects of the Invention] As described above, according to the present invention, a roof unit having a size that does not impair the transportation efficiency of the units constituting the unit building is used, and the workability and rain protection for the eaves of the unit building are improved. can improve sexual performance.

[Brief explanation of the drawing]

FIG. 1 is a schematic front view showing an embodiment of the present invention, FIG. 2 is a schematic perspective view of FIG. 1, and FIG. 3 is a schematic plan view of the tJS1 diagram. 10...Unit building. 11.12...Room unit. 13...Roof unit, 13A...Eave part. Patent applicant Sekisui Chemical Co., Ltd. Representative Hiroshi 1) Kaoru 1st Figure 2 Figure 3

Claims (2)

[Claims] (1) In a unit building in which a roof unit is mounted on the top surface of a room unit, the horizontal distance of the roof unit in the flow direction is greater than the width of the room unit along the flow direction of the roof unit, and the roof unit is perpendicular to the flow direction. The roof length of the roof unit is set to be smaller than the length of the room unit along the direction perpendicular to the flow of the roof unit, and the lower end of the slope of the roof unit in the flow direction protrudes from the widthwise end of the upper surface of the room unit to form an eaves part. A unit building characterized by: (2) In claim 1, the horizontal distance of the roof unit in the flow direction is approximately equal to the length of the room unit;
A unit building in which the roof length in the direction perpendicular to the flow of the roof unit is approximately equal to the length of the room unit divided by an integer.