JP2021055313A - Log wall structure - Google Patents

Abstract

To provide a building capable of improving wind resistance performance of a log wall without using a special processing technique or a new member, for example.SOLUTION: A structure of a log wall in a log house by a log construction method, comprises: horizontally stacking log members for the log house ; and a binding member connecting vertically adjacent log members to each other. The binding material hole for inserting the binding material is provided at a position deviated from the center in the width direction of the log material to the indoor side.SELECTED DRAWING: Figure 2

Description

The present invention relates to the structure of a log wall in the log assembly method.

Conventionally, it has been said that the design of the stress against the out-of-plane force due to the wind pressure of the log wall is sufficient with the shear strength of a dowel or a through bolt, which is a binding material provided in the log wall. For this reason, only the deviation in the horizontal direction is assumed, and the binding material is provided at the center in the width direction of the log material (Non-Patent Document 1).

Ministry of Land, Infrastructure, Transport and Tourism National Institute for Land and Infrastructure Management, Incorporated Administrative Agency Building Research Institute, Japan Building Administration Council, Japan Building Center, edited by Log House Association, "2003 Edition Log Assembly Technical Standards Explanation and Design / Calculation Examples" No. 2nd Edition, Engineering Books Co., Ltd., June 1, 2006

As shown in FIG. 13, the log wall is erected in the direction perpendicular to the ground. Here, when an out-of-plane force is generated by the wind, conventionally, as shown in FIG. 14, only the displacement in the horizontal direction is assumed, and the design is sufficient with the shear strength of the binding material such as a dowel or a through bolt.
However, in reality, as shown in FIG. 15, bending deformation of the log wall occurs due to an out-of-plane force due to wind pressure from the front direction of the log wall. It should be noted that FIGS. 10, 14 and 15 are schematic views for explanation only, and the modifications are exaggerated. In fact, such visible deformation does not occur.
That is, as shown in FIG. 15, the actual movement of the log wall when it receives the wind is deformed so that the vicinity of the center in the height direction of the log wall is convexly curved toward the indoor side. When such bending deformation of the log wall occurs, there is a problem that the binding material provided at the center in the width direction of the log material becomes inefficient as a wind resistant element as in the prior art. ..

Therefore, an object of the present invention is to provide a building capable of improving the wind resistance performance of a log wall without using a special processing technique or a new member or the like.

In order to solve the above problems, the first embodiment of the present invention is based on a log assembly method in which log materials for a log house are stacked horizontally and provided with a binding material for connecting the log materials adjacent to the top and bottom. The structure of the log wall in a log house
The binding material hole into which the binding material is inserted is provided at a position deviated from the center in the width direction of the log material toward the room side.

According to the first embodiment of the present invention, the binding material hole is misaligned from the center in the width direction of the log material to the indoor side, thereby increasing the bending strength of the log wall and increasing the rotational rigidity. Can be done.
This makes it possible to improve the wind resistance of the log wall without using special processing technology or new members.
Furthermore, compared to the case where the binding material hole is set at the center in the width direction of the log material, the wind resistance performance can be improved, so that the number of binding materials can be reduced, which is economical and planning in design. The degree of freedom is increased, and it becomes easier to meet various requests of the user (for example, wanting to provide many openings).

Further, in the second embodiment of the present invention, in addition to the configuration of the first embodiment, the distance of misalignment in the binding material hole is the width of the log material (specifically, the thickness of the log wall 10). It is characterized in that it is 5% or more and 30% or less with respect to the above.
According to the second embodiment of the present invention, the effect of increasing the rotational rigidity is expected, and at the same time, insufficient strength, deformation, breakage, etc. occur between the inner surface of the binding material hole and the indoor surface of the log material. It can be suppressed.
Further, the third embodiment of the present invention is characterized in that, in addition to the configuration of the first or second embodiment, the binding material is a dowel, and the dowel is embedded in the binding material hole. And.

According to the third embodiment of the present invention, the wind resistance of the log wall can be improved by applying the misalignment to the dowel as the binding material.

Further, in the fourth embodiment of the present invention, in addition to the configuration of the first or second embodiment, the binding material is a through bolt, and the binding material hole is formed in the uppermost stage of the log wall. The through bolt is installed so as to penetrate from the upper surface of the log material to the lower surface of the log material in the lowermost stage, and a washer is passed through the upper and lower ends of the through bolt and the bolt is fastened with a nut.

According to the fourth embodiment of the present invention, the wind resistance performance of the log wall can be improved by applying the misalignment to the through bolt as the binding material.

Further, in the fifth embodiment of the present invention, in addition to the configuration of the fourth embodiment, the nut located above the log material at the uppermost stage of the log wall is
The upper nut located on the upper surface of the washer and
It is a double nut having a lower nut located on the lower surface of the upper washer, which is the washer provided at the upper end of the through bolt.

According to the fifth embodiment of the present invention, the nut located above the log material at the uppermost stage of the log wall is a double nut having an upper nut and a lower nut. This double nut tightens the nut from the tightening space described later when the initial nut setting is loosened due to factors such as vibration, repeated stress, and settling peculiar to the log wall (sinking of the log wall due to shrinkage of the tree). It has the effect of preventing the threading bolt itself from turning.

Further, in the sixth embodiment of the present invention, in addition to the configuration of the fifth embodiment, the upper washer is
A horizontal portion having a through hole for the through bolt and being fixed to the upper surface of the log material,
It has a vertical portion that stands up from the horizontal portion, and has a vertical portion.
Arranged in a space having a right-angled triangular cross section between the upper surface of the log material at the uppermost stage of the log wall and the lower surface of the rafters fixed to the upper surface of the log material with a predetermined gradient. It is characterized by.

According to the sixth embodiment of the present invention, an L-shaped upper washer having a horizontal portion and a vertical portion that stands on the horizontal portion and has a height that does not abut on the lower surface of the rafters. Therefore, the rigidity of the upper washer can be increased as compared with a circular or quadrangular flat plate.
Further, since the cross section is L-shaped in this way, the upper surface of the log material at the uppermost stage of the log wall and the lower surface of the rafters on the roof having a slope located on the log wall are formed. The upper washer having an L-shaped cross section can be appropriately arranged in a space having a right-angled triangular cross section.
Furthermore, a through hole is used as a binding material hole for inserting a through bolt as a binding material, and the center of the log material in the width direction is displaced toward the room side, and the vertical part of the upper washer is the lower surface of the rafter and the log material. It is possible to easily fit between the upper surface and the upper surface of the.

According to the present invention, the binding material hole is misaligned from the center in the width direction of the log material to the indoor side, so that the bending strength of the log wall can be increased and the rotational rigidity can be increased, which is a special processing technique. It is also possible to improve the wind resistance of the log wall without using new members.

In the first embodiment of the present invention, an example of the structure of the log wall is schematically shown. It is a 1st Embodiment of this invention and is the top view of the binding material hole in a log material. It is the first embodiment of this invention, and is the partial sectional view of the through bolt in the log wall of FIG. It is the first embodiment of this invention, and is the partial sectional view of the through bolt in the log wall of FIG. It is the first embodiment of this invention, and is the schematic enlarged view of the log material and the dowel in the log wall of FIG. It is the first embodiment of this invention, and is the schematic enlarged view of the log material and the dowel in the log wall of FIG. FIG. 5 is a partial cross-sectional view of the first embodiment of the present invention in the case where an auxiliary column as a resistance member is provided on the log wall. It is the first embodiment of this invention, and is sectional drawing of the opening frame material in the opening frame of the opening of FIG. It is the first embodiment of the present invention, and is the schematic cross-sectional view in the case where a small out-of-plane force acts on a log wall having a dowel as a binding material. It is the first embodiment of the present invention, and is the schematic cross-sectional view in the case where a large out-of-plane force acts on the log wall having a dowel as a binding material. It is the 2nd embodiment of this invention, and is the schematic sectional view of the upper part of the log wall which arranged the L-shaped upper washer. It is a second embodiment of the present invention, and is a schematic top view of the upper part of the log wall in which the L-shaped upper washer is arranged. It is a schematic sectional view of a log wall. It is a schematic cross-sectional view in the case where an out-of-plane force due to wind acts on a log wall and only a deviation in the horizontal direction is assumed. It is a schematic cross-sectional view when the out-of-plane force by the wind acts on the log wall and bending deformation is assumed.

(First Embodiment)
Hereinafter, the structure of the log wall according to the embodiment of the present invention will be described with reference to the drawings.

As shown in FIG. 1, the log house 1 according to the present embodiment is mounted on a foundation 20 placed on the ground and fixed to the foundation 20 with anchor bolts 25 (not shown). It includes a base 30 (see FIG. 4) and a log wall 10 built on the base 30. The log wall 10 is constructed by a log assembly method in which logs, lumber and other similar log materials 11 are horizontally stacked.
Further, as shown in FIG. 1, an opening 70 is formed on at least one surface of the log wall 10 according to the present embodiment.

On the left side of the log wall 10, the left end side is in contact with the intersection 12 on the left side of the log material 11, while on the right side of the log wall 10, the right end side is in contact with the intersection 12 on the right side of the log material 11. The height of the log wall 10 is H (mm).

Then, through bolts 60 as a binding member 40 are provided on the left and right ends of the portion of the log wall 10 that does not have the opening 70.

Further, the log wall 10 is configured by connecting a plurality of log materials 11 to each other, and the log materials 11 are connected to each other by a dowel 50 as a binding material 40. The vertically adjacent dowels 50 are arranged in a staggered pattern. Two dowels 50 are provided on the left side of the log wall 10. Three dowels 50 are provided on the center side of the log wall 10. One dowel 50 is provided on the right side of the log wall 10.
In the present embodiment, as shown in FIG. 2, the dowel 50 as the binding material 40 and the binding material hole 41 into which the through bolt 60 is inserted are misaligned from the center in the width direction of the log material 11 toward the room side. It is provided at the position.
Specifically, as shown in FIG. 2, the center position of the log material 11 in the width direction with respect to the width W of the log material 11 (the position of W / 2 from the outdoor surface of the log material 11 shown in FIG. 2). A dowel 50 and a binding material hole 41 for inserting a through bolt 60 are provided on the indoor side at a position deviated by a distance X as described later.

Hereinafter, the through bolt 60 and the dowel 50 as the binding material 40 will be described.

The through bolt 60 in the present embodiment passes through the bolt holes 65 (see FIGS. 3 and 4) formed so as to penetrate from the uppermost stage to the lowermost stage of the log material 11, and is the most from the uppermost stage of the log material 11. Tighten the lower tier (see Fig. 1).
In the present embodiment, the through bolt 60 is used as a resistance member 90 that resists the wind pressure generated on the log wall 10.

Then, as shown in FIGS. 3 and 4, the through bolt 60 as the binding material is passed through the bolt hole 65 as the binding material hole, and the washer 61 is logged in the portion protruding from the uppermost stage and the lowermost stage of the log material 11. A nut 62 is attached between the material 11 and the log material 11 from the top to the bottom by tightening the nut 62.
That is, as shown in FIG. 4, the foundation 20 and the base 30 are fixed by anchor bolts 25. At this time, as shown in FIG. 4, the base 30 has a portion where the bases 30 adjacent to the left and right are discontinuous at the position of the through bolt 60, and the bases 30 adjacent to the left and right are between the bases 30. , The through bolt 60 penetrating from the uppermost stage to the lowermost stage of the log material 11 is used as a tightening space 32 for fixing with a nut 62. Further, in the tightening space 32, a box-shaped connecting member 36 in which two opposing surfaces are open among the six surfaces of the hexahedron is installed (however, the opening surfaces of the connecting member 36 face each other). It does not have to be two sides, it may be only one side). At this time, an opening portion (not shown) is provided on the lower surface of the connecting member 36, and the tip portion of the anchor bolt 25 protruding into the connecting member 36 through the opening portion is sandwiched between the washer 61 and the nut 62. By tightening, the connecting member 36 and the foundation 20 are fixed. As a result, the log material 11 at the bottom is fastened to the through bolt 60 by the washer 61 and the nut 62. In other words, the through bolt 60 and the foundation 20 are fixed to each other via the connecting member 36 and the anchor bolt 25. Further, as shown in FIG. 3, the log material 11 at the uppermost stage is also tightly bound to the through bolt 60 by the washer 61 and the nut 62.
Specifically, as shown in FIG. 1, through bolts 60 are provided at six locations on the log wall 10, and the log materials 11 at the uppermost stage to the lowermost stage are tied together at each location.

As shown in FIGS. 5 and 6, the dowels 50 in the present embodiment are provided at a plurality of locations different from the mounting positions of the through bolts 60 in a plan view, and the dowels 50 in each stage are staggered (staggered). ).
In this embodiment, the dowel 50 is used as a resistance member 90 that resists the wind pressure generated on the log wall 10.

A dowel 50 is provided at a different position in a plan view between the one log material 11 constituting the log wall 10 and the log material 11 one step below the one log material 11 in the present embodiment. Further, the dowel 50 is provided at the same position in the plan view of the one log material 11 and the log material 11 two steps below the one log material 11.

Here, as shown in FIG. 5, a lag screw can be used as the dowel 50. The length of the dowel 50 is about 1.5 times the length of the log material 11 in the vertical direction. The dowel 50 extends over half or more of the height dimension of the log material 11 on the upper side of the log material 11 adjacent to the top and bottom, and is separated from the core position of the log material 11 by a distance X in the indoor direction (so-called "core" described later). By being inserted vertically at the "misaligned" position and vertically inserted at the "misaligned" position of the log material 11 over half or more of the height dimension of the lower log material 11, the log material 11 is vertically inserted up and down. The log materials 11 adjacent to each other are connected to each other.
The "core" refers to a position in one log material 11 equidistant from both opposite sides in the lateral direction of the surface into which the dowel 50 is inserted.

In the present embodiment, the binding material hole 41 into which the binding material 40 is inserted is provided at a position deviated from the center in the width direction of the log material 11 toward the room side.

The dowel 50 in the present embodiment is vertically inserted over half or more of the height dimension of the log material 11 on the upper side of the log material 11 adjacent to the top and bottom, and the height dimension of the log material 11 on the lower side. It suffices if it covers more than half of the above, and it does not matter if it reaches the log material 11 one step below it.

As the dowel 50 in the present embodiment, a columnar dowel 50 (which may be made of wood or metal) as shown in FIG. 6 may be used. By inserting the dowel 50 into the upper hole 54 provided on the upper lower surface of the log material 11 adjacent to the upper and lower sides and the lower hole 56 provided on the upper surface of the lower stage, the log materials 11 adjacent to the upper and lower sides are connected to each other. Will be done. Such dowels 50 do not necessarily have to be provided alternately (staggered) as described above, and may be provided at the same position in a plan view.

In the present embodiment, for the purpose of reinforcement, a supplementary column 96 as a resistance member 90 may be provided along the log wall 10 or the column in the vertical direction (see FIG. 7).
FIG. 7 shows, as a specific example of the resistance member 90, an example in which the auxiliary column 96 is provided along the log wall 10 in the vertical direction.
The auxiliary column 96 is fixed to the log wall 10 by a lug screw 97.
In the present embodiment, the auxiliary column 96 is used as a resistance member 90 that resists the wind pressure generated on the log wall 10.

The opening frame of the opening 70 that opens to the log wall 10 according to the present embodiment is provided with opening frame members 72 that are vertical members on both sides of the opening 70 (see FIG. 1). As shown in FIG. 8, the opening frame material 72 has a T-shaped cross section, and is inserted into the end portion of the log material 11. Since the opening frame material 72 is formed in a T-shape in this way, it acts as a resistance to wind pressure and restrains the movement of the log material 11 in the out-of-plane direction.
Although not particularly shown, a sash or the like used by fitting glass or the like into the window frame is attached to the opening 70 between the opening frame members 72.
In the present embodiment, the opening frame member 72 is used as a resistance member 90 that resists the wind pressure generated on the log wall 10.

When the wind blows against the log house 1 whose peripheral side surface is surrounded by the log wall 10, an out-of-plane force due to the largest wind pressure is generated against the log wall 10 facing the direction in which the wind blows. ..
When an out-of-plane force due to wind pressure is generated on the log wall 10, the vicinity of the center of the log wall 10 in the height direction is deformed so as to be curved in a large convex shape toward the indoor side. When such bending deformation of the log wall 10 occurs, the binding material provided at the center of the log wall in the thickness direction becomes inefficient as a windproof element as in the conventional case.

Specifically, as shown in FIG. 9, it is assumed that a binding material hole 41 having a diameter of d3 for inserting the dowel 50 as the binding material 40 is formed inside the log wall 10 having a thickness W.
The position of the center (core) of the width W of the log material 11 in the width direction is the position of W / 2 from the side end surface of the log material 11.

Here, the distance d1 from the outdoor surface of the log material 11 to the center of the binding material hole 41 and the dowel 50, and the distance from the indoor surface of the log material 11 to the center of the binding material hole 41 and the dowel 50. The total with d2 is the thickness W of the log material 11.

In the width direction of the log material 11, the position of the center of the binding material hole 41 and the dowel 50 as the binding material 40 is only a distance X from the position of the core which is the center in the width direction of the log wall 10 as shown in FIG. It is shifted to the indoor side. That is, the binding material hole 41 is provided at a so-called misaligned position, which is separated from the position of the center (core) in the width direction of the log material 11 by a distance X to the indoor side.
As shown in FIG. 10, when a strong wind blows from the outdoor side to the log wall 10, the log material 11 of the log wall 10 is deformed so as to be curved toward the indoor side due to the out-of-plane force due to the wind pressure. The outdoor edge portion serves as a fulcrum 13, and in the log material 11, the upper log material 11a and the lower log material 11b rotate around the fulcrum 13 as the center of rotation.

At that time, the dowel 50 fitted in the binding material hole 41 becomes a resistance force for the rotational movement due to the frictional force on the surface of the dowel 50 or the like. Therefore, according to the principle of leverage, the larger the distance d1 from the fulcrum 13, the greater the resistance to rotational movement between the upper log material 11a and the lower log material 11b. That is, from another viewpoint, the larger the distance X from the center of the log material 11 in the width direction to the center of the binding material hole 41 and the dowel 50, the larger the upper log material 11a and the lower log material 11b become. The resistance to rotational movement increases. As a result, the larger the misalignment distance X, the higher the rotational rigidity.

This distance X is a distance at which the centers of the binding material holes 41 and the dowels are separated from the center in the width direction of the log material 11 toward the room side, that is, a so-called misaligned distance.
As a result, the rotational rigidity of the log material 11a and the log material 11b can be increased so that the arrangement of the binding material hole 41 and the dowel is misaligned from the center in the width direction of the log material 11 toward the indoor side. The more the center is displaced, the more the log wall 10 can be suppressed from bending and deforming.

Here, the "misalignment distance X" at the position where the log wall 10 is misaligned by the distance X in the indoor direction is an optimum value according to the reference wind speed for each region and the density of buildings in each region. Is set. Further, the value may be changed for each log wall 10 on all sides of the log house 1 according to the prevailing wind.
Specifically, the misalignment distance X is 5% or more and 30% or less with respect to the thickness (the width of the log material 11 and W in FIG. 9) of the log wall 10. It is preferable to set it at a corresponding distance.
When the "distance X" of the misalignment is less than 5%, the binding material hole 41 is misaligned from the center in the width direction of the log material 11 toward the room side, which has the effect of increasing the rotational rigidity as described above. It is not expected, and the meaning of causing misalignment becomes poor.
On the other hand, when the distance X exceeds 30%, the distance between the inner surface of the binding material hole 41 and the indoor surface of the log material 11 becomes small, the strength between them becomes insufficient, and the binding material hole 41 becomes the log material. There is a possibility that the 11 is deformed to the indoor side, or the binding material hole 41 and the indoor surface of the log material 11 are damaged.
Further, in consideration of the reduction rate η of the shear strength Q according to the misalignment, which will be described later, the distance d2 from the indoor surface of the log material 11 to the center of the binding material hole 41 and the dowel 50 is the binding material hole 41. It is more preferable that the diameter is twice or more the diameter d3 of the binder hole 41, and it is further preferable that the diameter d3 of the binding material hole 41 is three times or more.

In the present embodiment, the shear strength Q of the binding material is a value obtained by multiplying the reduction rate η according to the misalignment distance X. Generally, F _C, which will be described later if no is generated _{misalignment,} based on sigma _y, d, conditions such as D, the equation to be described later, the calculation of shear strength Q per one dowel 50 It becomes possible (see "2003 version of log assembly method technical standard explanation and design / calculation example" of Non-Patent Document 1).
For example, although details are omitted, the shear strength Q per dowel 50 is calculated by the numerical value that is the minimum value among the numerical values of the following (Equation 1) to (Equation 4).

Q = 1 / 2F _C dD ・ ・ ・ ・ ・ ・ ・ ・ ・ ・ ・ ・ ・ (Equation 1)

_{^{Q = (((19) 1/2}} -3) / 4) F C dD ··············· ( Equation 2)

Q = (((4 + 2 (σ y / F C) (2d / D) 2) 1/2 -1) / 6) F C dD · ( Equation 3)

_{Q = (1/3 (σ y /} F C)) 1/2 F C d 2 ················ ( Equation 4)

However, _{F C:} fiber direction compressive strength of the round timber such as (N / ^mm 2)
σ _y : Yield strength of dowel steel (standard strength of steel) (N / mm ² )
d: Dowel diameter (mm)
D: Found height of log material (mm)

Here, when misalignment is generated as in the present embodiment, the shear strength in the out-of-plane direction is calculated by multiplying the above-mentioned shear strength Q by the reduction rate η according to the misalignment. It becomes possible.
Here, the reduction rate η is calculated by (Equation 5).

η = min {d1, d2} / 4d3 (η ≦ 1.0) ・ ・ ・ ・ ・ ・ (Equation 5)

However, d1 and d2 mean the distance from the outdoor surface and the indoor side surface of the log material 11 shown in FIG. 9 to the center of the binding material hole 41, and d3 means the diameter of the binding material hole 41, and d3 also means the diameter of the binding material hole 41. min {d1, d2} means to select the smaller numerical value of d1 and d2.
This makes it possible to perform an evaluation in the out-of-plane direction in consideration of a reduction in the shear strength of the binding member 40 due to misalignment.
In the above equation, in order to set the reduction rate η to 1, a distance four times the diameter d3 of the binding material hole 41 is set to be required for d1 and d2.

For reference, when the dowel 50 is misaligned from the center position of the width W of the log material 11, the short-term allowable bending strength Y (kNm) and the rotational rigidity Z (for bending of the dowel joint in the out-of-plane direction) It is being studied to multiply kNm / rad) by the correction coefficient β according to the position of the misalignment.

W: Width of log material d1: Distance from the outdoor surface to the center of the dowel β = d1 / (W / 2)
For example, when the width W of the log material is 100 mm, the correction coefficient β = d1 / 50.

Here, the correction coefficient β is used as a reduction coefficient when the center is misaligned to the outdoor side, but is 5% (that is, that is, 5% (that is,) with respect to the dimension of the width W of the log wall 10 as in the present embodiment. When the misalignment X (0.05W to 0.30W) toward the indoor side corresponding to the distance of 0.05W) or more and 30% (that is, 0.30W) or less is set, the correction coefficient β is simply set. When applied to, the correction coefficient β is considered to function as an extra coefficient when the center is misaligned toward the room side.

Specifically, as shown in FIG.
d1 = W / 2 + X (distance of misalignment)
= W / 2 + (0.05W to 0.30W)
= 0.55W ~ 0.80W
When β is calculated by substituting this d1 into the correction coefficient β described above,
β = (0.55W to 0.80W) / (W / 2)
= 1.1 to 1.6

That is, in the present embodiment, the short-term allowable bending stress of 1.1 to 1.6 times, that is, 1.1Y, as compared with the case where the dowel 50 is installed at the center of the width (thickness) of the log material 11. The numerical values of about 1.6Y (kNm) and the rotational rigidity of 1.1Z to 1.6Z (kNm / rad) are calculated as a tentative guideline.
In the present embodiment, it is expected that the short-term allowable bending stress and the rotational rigidity will be improved to the above-mentioned degree due to the misalignment X toward the indoor side as described above, and the wind resistance performance of the log wall 10 is expected to be improved.

According to the present embodiment, the binding material hole 41 is misaligned from the center in the width direction of the log material 11 toward the room side by a distance X, thereby increasing the bending strength of the log wall 10 and increasing the rotational rigidity. Can be enhanced.
Thereby, the wind resistance performance of the log wall 10 can be improved without using a special processing technique or a new member.
Further, as compared with the case where the binding material hole 41 is set at the center in the width direction of the log material 11, the wind resistance performance can be improved, so that the number of binding materials 40 can be reduced, which is economical and economical. The degree of freedom in planning in design is increased, and it becomes easier to meet various requests of users (for example, wanting to provide many openings 70).
Similarly, as a resistance member 90 that resists the wind pressure generated in the log wall 10 by improving the wind resistance performance as compared with the case where the binding material hole 41 is set at the center in the width direction of the log material 11. The number of dowels 50, through bolts 60, auxiliary columns 96, opening frame members 72, etc. can be reduced, and instead of reducing the number, or in addition, the size of the resistance members 90 thereof is reduced. It can be changed to a new one, which is economical, increases the degree of freedom in planning in design, and makes it easier to meet various requests of users.

Further, in the present embodiment, the dowel 50 is provided as the binding material 40, and the dowel 50 is embedded in the binding material hole 41.

Then, by applying the misalignment to the dowel 50 as the binding material 40, the wind resistance of the log wall 10 can be improved.

In the present embodiment, the through bolt 60 is provided as the binding member 40, and the misalignment is applied to the through bolt 60 as well as the above-mentioned dowel 50.
That is, the through bolt 60 as the binding material 40 also has the bolt hole 65 as the binding material hole 41 through which the through bolt 60 as the binding material 40 is passed, and the width of the log material 11 is the same as the misalignment of the dowel 50. It is deviated from the center position in the direction toward the room.
The binding material hole 41 into which the through bolt 60 as the binding material 40 is inserted penetrates from the upper surface of the log material 11 at the uppermost stage of the log wall 10 to the lower surface of the log material 11 at the lowermost stage. A through bolt 60 is inserted into the binding material hole 41, and a log material 11 is fastened by a nut 62 through a washer 61 at the upper and lower ends of the through bolt 60.

According to this embodiment, the wind resistance performance of the log wall 10 can be improved by applying the misalignment to the through bolt 60 as the binding material 40.

(Second Embodiment)
A second embodiment will be described with reference to FIGS. 11 and 12.
In the present embodiment, as in the first embodiment, the through bolt 60 is provided as the binding member 40, and the misalignment is similarly applied to the through bolt 60.
Then, as in the first embodiment, the binding material hole 41 penetrates from the upper surface of the log material 11 at the uppermost stage of the log wall 10 to the lower surface of the log material 11 at the lowermost stage, and a through bolt 60 is installed. Then, a washer 61 is passed through the upper and lower ends of the through bolt 60 and is fastened by a nut 62.

Further, in the present embodiment, as shown in FIG. 11, the nut 62 located on the upper side of the log material 11 on the uppermost stage of the log wall 10 is the upper nut 63 located on the upper surface of the washer 61 and the lower surface of the washer 61. It is a double nut having a lower nut 64 located at.

In the present embodiment, the upper washer 210 is used as the washer 61 for the through bolt 60 of the log wall 10, which is located above the log material 11 at the uppermost stage of the log wall 10.
As shown in FIGS. 11 and 12, the upper washer 210 has a through hole 220 that penetrates vertically for the through bolt 60, and has a horizontal portion 230 fixed to the upper surface of the log material 11 and the horizontal portion 230. It is erected in a vertical portion 240 and has a height that does not come into contact with the lower surface of the rafter 201.
The upper washer 210 has a right-angled triangular cross section between the upper surface of the log material 11 at the uppermost stage of the log wall 10 and the lower surface of the rafter 201 fixed to the upper surface of the log material 11 with a predetermined gradient. Arranged in space.

According to the present embodiment, as shown in FIG. 11, the nut 62 located above the log material 11 at the uppermost stage of the log wall 10 is a double nut having an upper nut 63 and a lower nut 64.
When the initial setting of the nut 62 is loosened due to factors such as vibration, repeated stress, and settling peculiar to the log wall 10 (sinking of the log wall 10 due to contraction of the log material 11 made of wood), this double nut is used. There is an effect of preventing the through bolt 60 itself from turning when the nut 62 is tightened from the tightening space 32.

According to the present embodiment, an L-shaped upper washer 210 having a horizontal portion 230 and a vertical portion 240 erected on the horizontal portion 230 and having a height that does not abut on the lower surface of the rafter 201 is formed. Therefore, the rigidity of the upper washer 210 can be increased as compared with the circular or quadrangular flat washer.
By forming the L-shaped upper washer 210, when the nut 62 is tightened from the tightening space 32 as described above, the highly rigid upper washer 210 is pressed against the log material 11 on the widest possible surface. , The rotational force on the through bolt 60 can be received.
Further, since the cross section is L-shaped, the slope of the upper surface of the log material 11 at the uppermost stage of the log wall 10 and the lower surface of the rafter 201 in the roof 200 located on the log wall 10 can be set. The upper washer 210 having an L-shaped cross section can be appropriately arranged in a space having a right-angled triangular cross section.
Further, the binding material hole 41 for the through bolt 60 as the binding material 40 is misaligned from the center in the width direction of the log material 11 toward the room side, so that the vertical portion 240 of the upper washer 210 is the rafter 201. It is easy to fit between the lower surface and the upper surface of the log material 11. As a result, the upper washer 210 having an L-shaped cross section can be appropriately arranged in the space as described above.
Specifically, when an L-shaped upper washer 210 having the same height of the vertical portion 240 and the width of the horizontal portion 230 is adopted to prevent the through bolt 60 from being misaligned, that is, a log material. If it is attempted to be arranged in the center in the width direction of 11, it will hit the lower surface of the rafter 201 of the roof 200, and if there is no countermeasure such as increasing the inclination angle of the slope of the roof 200 as it is, the upper washer 210 should be arranged. May occur.
By shifting the through bolt 60 toward the room by a distance X as in the present embodiment, such a situation can be avoided.

1 Log house 10 Log wall 11 Log material 11a Upper log material 11b Lower log material 12 Crossing 13 A fulcrum d1 Distance from the outdoor surface of the log wall to the center of the binding material hole d2 Bonding from the indoor surface of the log wall Distance to the center of the material hole 20 Foundation 25 Anchor bolt 30 Base 32 Tightening space 36 Connecting member 40 Binding material 41 Binding material hole 50 Dowel 54 Upper hole 56 Lower hole 60 Through bolt 61 Washer 62 Nut 63 Upper nut 64 Lower nut 65 Bolt Hole 70 Opening 72 Opening frame material 90 Resistance member 96 Attached pillar 97 Lag screw 200 Roof 201 Lap tree 210 Upper washer 220 Through hole 230 Horizontal part 240 Vertical part

Claims (6)

It is a structure of a log wall in a log house by a log assembly method, in which log materials for a log house are stacked horizontally and a binding material for connecting the log materials adjacent to the top and bottom is provided.
The structure of the log wall, characterized in that the binding material hole into which the binding material is inserted is provided at a position deviated from the center in the width direction of the log material toward the room side. The log wall structure according to claim 1, wherein the misalignment distance in the binding material hole is 5% or more and 30% or less with respect to the width of the log material. The log wall structure according to claim 1 or 2, wherein the binding material is a dowel, and the dowel is embedded in the binding material hole. The binding material is a through bolt and
The through bolt is installed in the binding material hole through the upper surface of the log material at the uppermost stage of the log wall to the lower surface of the log material at the lowermost stage, and a washer is passed through the upper and lower ends of the through bolt. The log wall structure according to claim 1 or 2, wherein the log wall is fastened by a nut. The nut located above the log material at the top of the log wall is
The upper nut located on the upper surface of the washer and
The log wall structure according to claim 4, wherein the log wall structure is a double nut having a lower nut located on the lower surface of the upper washer, which is the washer provided at the upper end of the through bolt. The upper washer is
A horizontal portion having a through hole for the through bolt and being fixed to the upper surface of the log material,
It has a vertical portion that stands up from the horizontal portion, and has a vertical portion.
Arranged in a space having a right-angled triangular cross section between the upper surface of the log material at the uppermost stage of the log wall and the lower surface of the rafters fixed to the upper surface of the log material with a predetermined gradient. The structure of the log wall according to claim 5.

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