JP2005188722A - Drift pin - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a drift pin that can simplify and reduce the cost when executing the construction and avoid the looseness of the framework even if a pillar and a horizontal member becomes slim by expansion and contraction of the pillar and the horizontal member. <P>SOLUTION: It is inserted into the latch holes 32, 33, 42, 43 that are formed in a pillar 3 and a beam 4 and the penetration holes 16a, 16b, 17a, 17b that are formed to a connection metal fittings 1 corresponding to the penetration holes. The drift pin 2 is made of metal bar member and composed of a drift pin body 21 which can expand and contract the outer diameter dimension of the drift pin body 21 between smaller initial condition P than the inner diameter dimension of the penetration holes 16a, 16b, 17a, 17b of the above metal fitting 1 and more expansion condition Q than equivalent inner diameter to these penetration holes 16a, 16b, 17a, 17b and an engagement member 22 that can make the drift pin body 21 in the expansion condition by making engage to the insertion hole 21d of the drift pin body 21 in the inserted condition the latch holes 32, 33, 42, 43, of the pillar 3 and the beam 4 of the penetration holes 16a, 16b, 17a, 17b of the connection metal fitting 1 in an initial state P. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a drift pin used when joining wooden pieces in a wooden frame construction method.

  Conventionally, in a wooden frame construction method that joins a pillar of a wooden building and a horizontal member such as a beam or a crosspiece, various methods of fixing the horizontal member to the pillar with a connecting bracket, bolts and drift pins have been considered. . The connection bracket used in the wooden frame construction method is mainly a plate-like plate, with a protrusion that has a screw hole formed at one end of the plate, and is provided on the upper edge of the plate. In general, a through-hole corresponding to the locking hole formed in is formed. That is, such a connection fitting is a through-hole formed so that a protrusion is first inserted into a side hole formed on one side of the column and communicated with the side hole on the side opposite to or adjacent to the side. The bolt inserted into the hole is fixed to the pillar by screwing into the screw hole of the protrusion. Then, with the plate inserted into the vertical slit formed at the side edge of the horizontal member such as a beam or a beam joined to this column, the bolt is passed through the locking hole of the horizontal member and the through hole of the plate Then, the horizontal member is fixed to the connection fitting by tightening with a nut. Thereby, the conventional wooden frame construction method is configured such that the column and the horizontal member are joined via the connection fitting.

  However, in such a construction method, a large number of bolts are used to join the pillar and the horizontal member, so the work becomes complicated because the bolts are tightened. Time, resulting in an increase in construction and dismantling costs.

  In order to solve the above-described problems, a method of joining using a drift pin instead of a bolt is considered. In other words, this method fixes the connecting bracket, column, and horizontal member by simultaneously hitting the drift pin, which is a metal rod-shaped member, by hitting it with a hammer or the like into the site where the bolt has been inserted. It is intended to stabilize the frame structure by allowing the pins themselves to bite into wooden columns and horizontal members.

  However, since the pillars and horizontal members are made of wood, the expansion and contraction is repeated as time goes on, so that after a long time, it will eventually fade, so the locking hole into which the drift pin is driven will expand. Thus, there is a risk that the shaft structure is loosened or the drift pin falls off.

In order to solve such a problem, there has been proposed a drift pin configured so as not to easily come off from wood. As this type of drift pin, for example, a plurality of screw blade-shaped tail portions protruding on its axis (for example, see Reference 1), or a plurality of tail portions having a triangular sawtooth shape are used. (For example, Reference 2). In other words, the drift pin formed with multiple screw blade-shaped ends is configured so that when the hammer or the like is driven into a pillar or horizontal member, the drift pin moves with the screw blade while rotating, and the screw blade bites into the wood. On the other hand, a drift pin with a sawtooth shaped beveled portion can be wedged into a piece of wood by hitting a pillar or horizontal member with a hammer etc. It is configured. That is, these drift pins are intended to join the pillar and the horizontal member with high strength via the connecting metal fitting by causing the edge portion to bite into the wood in this way.
Published JP-A-8-21905 Published Japanese Patent Laid-Open No. 10-159186

  However, even if such a drift pin is used, the pillar and the horizontal member will become thin after a long time has passed since the operation, and the part of the wood that bites into the edge of the drift pin will expand, causing the pillar and the horizontal The engagement between the frame member and the drift pin will be loosened, and as a result, the entire shaft structure may be loosened. In addition, because the drift pin protrudes from the drift pin, it is difficult to remove the drift pin from the column or horizontal member by hitting it with a hammer or the like when dismantling the building. The horizontal members must be destroyed, making it difficult to reuse these timbers.

  Therefore, in view of the above problems, the present invention can simplify construction and reduce the cost during construction work. Furthermore, due to expansion and contraction of the columns and horizontal members, the shafts and horizontal members can be thinned. The main purpose is to provide a drift pin for preventing the set from loosening.

  That is, it is used in a wooden frame structure in which a pillar made of wood according to the present invention and a horizontal member such as a beam are joined by engaging a connecting bracket between them, and the latch formed on the pillar and the horizontal member. It is inserted into a hole and a corresponding through-hole formed in the connection fitting, and is a line segment that connects two points on the periphery in a cross section that is made of a metal rod-like member and is orthogonal to the longitudinal direction. A drift pin body capable of expanding / contracting between an initial state in which the maximum length is smaller than the inner diameter dimension of the through hole of the connection fitting and an expanded state equal to or greater than the inner diameter of the through hole, and the column and the horizontal mount in the initial state And an engaging member that can bring the drift pin body into the expanded state by engaging with a predetermined portion inside the drift pin body in a state of being inserted into the locking hole of the material and the through hole of the connecting metal fitting. Is.

  In the case of an expandable / contractable drift pin having such a configuration, the drift pin body in the initial state is inserted into the locking holes of the pillar and the horizontal member and the through holes of the connection fitting, and is engaged with the predetermined position of the drift pin body. When the members are engaged, the drift pin main body forms an expanded state, and the drift pin main body has an outer diameter dimension greatly changed to engage with the through hole of the connection fitting. As a result, the drift pin body bites into the through hole of the connection fitting, and the drift pin can be firmly fixed to the connection fitting, and the column and the horizontal member can be firmly joined together. Furthermore, in that case, after the construction of the shaft assembly, the pillars and horizontal members will fade after a long time, and even if the part of the wood where the drift pin is bitten expands, the drift pin and the connecting bracket Because it is fixed directly and firmly, the engagement between the pillar and horizontal member and the drift pin will loosen after fixing the locking hole formed in the column and horizontal member and the through hole formed in the connecting bracket. Furthermore, it is not possible for the entire frame structure to be loosened. Further, when the engaging member is engaged with a predetermined portion embedded in the drift pin main body, the outer peripheral edge of the drift pin main body has no protrusion and the engaging member protrudes. Therefore, the structure of the drift pin itself and the shaft assembly can be simplified. In addition, when dismantling a building, etc., it is easy to remove the drift pin from the pillar and horizontal member by hitting the drift pin with a hammer, etc., so that the pillar and horizontal member are not destroyed. It is possible to reuse these woods.

  In addition, if the slit is formed along the longitudinal direction of the drift pin body, and the engagement member is engaged with the drift pin body in the initial state, the opening width of the slit is widened. It is possible to easily realize a structure in which the pin body can be easily expanded.

  In this case, in order to make it possible to easily expand the opening width of the slit so that the engaging member can be smoothly inserted into and engaged with the drift pin body from the opposite insertion end to the insertion hole, An insertion hole communicating with the slit is formed at the opposite insertion end with respect to the locking hole of the column and the horizontal member of the main body, and the engagement member is inserted into the insertion hole from the opposite insertion end. It is effective to insert and engage the engaging member from the side opposite to the insertion end.

  Further, in order to change the drift pin body from the initial state to the expanded state, it is preferable that the engaging member is a member having a rod shape having an outer diameter dimension equal to or larger than the inner diameter dimension of the insertion hole.

  As described above in detail, that is, if the drift pin of the configuration of the present invention can be expanded and contracted, by forming the expanded state by engaging the engagement member with the drift pin body in the initial state, The drift pin main body bites into the through hole of the connection fitting for connecting the column and the horizontal member, and the connection fitting and the drift pin are firmly fixedly engaged with each other. Therefore, after the construction of the wooden framed building, after fixing the pillar and beam to the connection bracket, the wood part that has been devoured by the drift pin and the drift pin has been swollen over a long period of time as the long time has passed. In addition, even if the connection between the pillar or beam and the drift pin is loosened, the connection fitting and drift pin will not be loosened. It can never happen. Further, by engaging the engaging member with the insertion hole of the drift pin body, the drift pin body can be simplified because there is no protrusion at the outer peripheral edge. Furthermore, when demolishing a building or the like, it is easy to remove the drift pin from the pillar or beam, so that the wood can be reused without destroying the pillar or the beam.

  Hereinafter, an embodiment of the present invention will be described with reference to the drawings.

  The drift pin 2 according to the present embodiment is joined as a wooden frame structure for connecting the pillar 3 and the beam 4 as a horizontal member in the wooden frame construction method with the connection fitting 1 interposed therebetween as shown in FIG. This is applied to the structure X.

  The drift pin 2 has a drift pin main body 21 formed so as to be expandable / contractable by an external force, and an engagement member 22 that can engage with the drift pin main body 21 and expand the outer dimension of the drift pin main body 21 to an expanded state. It consists of and. FIG. 2A is an exploded perspective view of the drift pin 2 in a state (initial state P) before the engagement member 22 is inserted into the drift pin main body 21, and FIG. The perspective view of the drift pin 2 of the state (expanded state Q) after inserting is shown. 3A is an end view taken along line AA in FIG. 2A, and FIG. 3B is an end view taken along line BB in FIG. 2B.

  The drift pin main body 21 has a substantially cylindrical shape made of a metal rod-like member, and has a longitudinal dimension substantially the same as the width dimension of the column 3 or the beam 4 to be applied. In the present embodiment, the maximum value of the diameter of the drift pin body 21 is, for example, about 11 mm, and the longitudinal dimension is about 100 mm. Then, one end of the drift pin main body 21 is inserted into a predetermined position between the pillar 3 and the beam 4 and the connection fitting 1 in order to fix the pillar 3 and the connection fitting 1 or the beam 4 and the connection fitting 1. This is the insertion end 21a which becomes the side. The insertion end 21a is formed in a tapered shape having a length of about one-tenth of the longitudinal dimension so that the insertion at the predetermined position is easy. The other end of the drift pin main body 21 forms the opposite side of the insertion end 21a and the opposite insertion end 21b for inserting the engaging member 22. In addition, a straight slit 21c having a depth from the outer surface to the central portion in the diameter direction is formed in the entire longitudinal dimension of the drift pin main body 21. In this embodiment, the opening width of the slit 21c is, for example, about 1 to 2 mm. Then, in the entire longitudinal dimension of the drift pin main body 21 from the non-insertion end 21b to the insertion end 21a, about one third of the outer diameter of the drift pin main body 21 from the center toward the insertion end 21a. An insertion hole 21d having a diameter (for example, about 3 mm in this embodiment) and having a longitudinal dimension slightly shorter than the longitudinal dimension of the drift pin main body 21 is formed, and this insertion hole 21a is further formed in the slit 21c. Communicate. One parallel slit 21c having a width of about 1 to 2 mm is formed over the entire length of the drift pin body 21 in the longitudinal direction. The drift pin main body 21 in this case forms an initial state, and the drift pin main body 21 when the engaging member 22 is inserted into the insertion hole 21d forms an expanded state.

  On the other hand, the engagement member 22 is inserted and inserted into the insertion hole 21d from the counter-insertion end 21b side of the drift pin main body 21 with a hammer or the like (not shown). The member which makes is applied. The diameter of the engaging member 22 is for displacing the drift pin main body 21 from the initial state to the expanded state. The engaging member 22 has a cylindrical shape having a diameter that is slightly larger (for example, about 3.1 to 3.2 mm) than the diameter of the opening 21d formed in the counter-insertion end 21b of the drift pin body 21. The longitudinal dimension is equal to the longitudinal dimension of the drift pin main body 21 or slightly shorter than the insertion hole 21d. When the engaging member 22 is driven into the insertion hole 21d from the side opposite to the insertion end 21b with a tool such as a hammer with respect to the drift pin main body 21 in the initial state P shown in FIG. As in the expanded state Q shown in b), the outer dimensions of the drift pin main body 21 are made larger.

  Next, the joint structure X to which such a drift pin 2 is applied is constituted by simply explaining the connection fitting 1 that joins the pillar 3 and the beam 4 constituting the structure. In addition, the pillar 3, the beam 4, and the connection metal fitting 1 are the normal wood which the pillar 3 makes the prismatic shape about 105 mm, for example, Comprising: The single beam 4 is joined only to one side surface 3a. In this case, a square hole 31 for inserting the connection fitting 1 is opened at the center in the width direction at a predetermined height position of the side surface 3a. The width dimension and the height dimension of the hole 31 correspond to the width dimension and the height dimension of the connection fitting 1, and the depth in the horizontal direction of the hole 31 is the thickness of the column. About one third. In addition, since the pillar 3 is fixed to the connection fitting 1 via the connection fitting 1, a pair of locking holes 32 spaced apart from each other by a predetermined distance passing through the hole 31 substantially horizontally so as to communicate with the connection fitting 1. 33 are penetrated through the pillar 3. The diameters of the locking holes 32 and 33 are substantially equal to or slightly smaller than the diameter of the drift pin body 21 in the initial state P.

  Next, the beam 4 is, for example, a normal wood having a prismatic material having a width of about 105 mm and a height of about 150 mm, and a corner for inserting the connection fitting 1 at the center in the width direction of the side end surface 4a. A groove-like recess 41 is formed by opening in the vertical direction. The opening width dimension of the recess 41 is slightly larger than the width dimension of the connection fitting 1, and the height dimension is the same as the beam height dimension. In addition, since the beam 4 is fixed via the connection fitting 1, a pair of locking holes 42 that are spaced apart from each other by a predetermined distance passing through the recess 41 substantially horizontally so as to communicate with the connection fitting 1. 43 is formed through the beam. The diameters of the locking holes 42 and 43 are substantially equal to or slightly smaller than the diameter of the drift pin main body 21 in the initial state P.

  The connection fitting 1 for joining the column 3 and the beam 4 is formed of a rectangular metal plate having a thickness of about 2 to 3 mm. The connection fitting 1 is a hollow angle penetrating vertically. The main body is a metal fitting body 10 that forms a cylindrical shape. The bracket body 10 includes a rectangular front plate 11 opposed to the front and rear, a rear plate 12, and a pair of left and right side plates 13 disposed between the front plates 11 and the side edges of the rear plate 12. , 14 are integrally formed by welding or the like. In addition, between the front plate 11 and the rear plate 12 in the center in the width direction, a reinforcing plate 15 having the same rectangular shape as that of the side plates 13 and 14 is welded between the inward facing surfaces of the metal plate by welding or the like. 1 is fixed. Then, a region on one side end portion side (left half in FIG. 1) with the reinforcing plate 15 as a boundary is a column side insertion portion 16 for connecting to the column, and a half on the other end side (see FIG. The area on the right half in FIG. 1 is a beam side insertion portion 17 for connecting to a beam. Further, in the column side insertion portion 16, a through hole 16 a that is separated from the front plate 11 and the rear plate 12 by a predetermined distance in a substantially horizontal direction so as to communicate with the locking holes 32 and 33 formed in the column 3. 16b are formed. On the other hand, the beam side insertion portion 17 is formed with through holes 17a and 17b spaced apart from each other by a predetermined distance so as to communicate with the locking holes 42 and 43 formed in the beam 4 like the column side insertion portion 16. The through holes 16a, 16b, 17a, 17b are formed with a diameter slightly larger than the diameter of the drift pin body 21 in the initial state. Moreover, this connection metal fitting 1 can be used also in the attitude | position which reversed up and down, left and right.

  4 and 5A are cross-sectional views when the drift pin main body of FIG. 4 cross-section CC is in the initial state, and FIG. 4B is a cross-sectional view of FIG. FIG. In such a configuration, at the time of construction of the joint structure X in which the shaft assembly of the pillar 3 and the beam 4 is joined, the pillar-side insertion portion 16 of the connection fitting 1 is first formed in the pillar 3 as shown in FIG. The drift pin main body 21 in the initial state P is formed in the locking holes 32 and 33 of the pillar 3 and the through holes 16a and 16b of the connection fitting 1 which are inserted into the hole 31 and communicated in this state. Insertion is performed by hitting the insertion end 21b with a tool such as a hammer. In this state, as shown in FIG. 5A, the drift pin body 21 is not attached to the connection fitting 1 because the diameter of the drift pin body 21 in the initial state P is smaller than the through holes 16 a and 16 b of the connection fitting 1. Not engaged. Furthermore, from this state, the drift pin main body 21 is inserted into the insertion hole 21d formed in the anti-insertion end 21b from the counter-insertion end 21b side of the drift pin main body 21 using a tool such as a hammer (not shown). As shown in FIGS. 4 and 5 (b), when the engagement member 22 is inserted, the opening width of the slit 21c of the drift pin body 21 is widened to be in the expanded state Q, and the outside of the drift pin body 21 is removed. As a result, the diameter of the drift pin main body 21 bites into the through holes 16a and 16b of the connection fitting 1 and is firmly engaged. The engaging member 22 is held by being driven and engaged from the opposite insertion end 21b side to the insertion end 21a side. At this time, when the engaging member 22 is driven, a lubricant such as volatile spray oil is sprayed on the insertion hole 21d of the drift pin main body 21 or the engaging member 22, so that Welding due to the ability to reduce the frictional resistance that occurs during insertion between the drift pin main body 21 and the engagement member 22 that are metal members is prevented. The drift pin main body 21 is in an expanded state in which the outer diameter dimension of the drift pin main body 21 is slightly changed by the engaging member 22 held by the drift pin main body 21 as the slit 21c is formed. Will be formed. As a result, the drift pin 2 integrally formed in this way is fitted with no gap when the drift pin 2 is kept expanded from the inner diameter of the through hole 16A6b formed in the connection fitting 1. To bite. As a result, the connecting pin 1 and the drift pin 2 are configured so that the drift pin 2 is not pulled out of the through hole 16A6b formed in the connecting member 1, so that Fixing is possible. Accordingly, in this state, the connection fitting 1 is pulled out from the hole 31 of the pillar 3 in the anti-insertion direction unless the engagement member 22 is extracted from the drift pin main body 21 of the drift pin 2 configured integrally. There is no. After the connection fitting 1 is thus attached to the pillar, the side end face 4a of the beam 4 is brought close to the pillar 3 and the beam insertion portion 17 of the connection fitting 1 is inserted into the recess 41 formed in the beam 4. In this state, the drift pin main body 21 in the initial state P is driven into the through holes 17a and 17b communicating with the locking holes 42 and 43 formed in the beam 4 in the same manner as the fixing work of the connection fitting 1 to the column 3. Then (see FIG. 5A), the engagement member 22 is driven into the insertion hole 21d formed in the drift pin main body 21 using a tool such as a hammer (not shown) to engage the engagement member 22. I'm. By doing in this way, the drift pin main body 21 expands the opening width | variety of the slit 21c, the expanded state Q is formed, and the drift pin main body 21 and the engaging member 22 are comprised integrally. Then, the outer peripheral surface of the drift pin main body 21 is fitted into the through holes 17a and 17b of the connection fitting 1 without any gap and slightly bites so that the drift pin 2 is not pulled out of the connection fitting 1. And the column 3 can be firmly fixed to the beam 4. As a result, the joining structure X is configured by joining the column 3 and the beam 4 together so that they are firmly joined via the connection fitting 1 and the drift pin 2. . By constructing the joint structure X as described above, the connection fitting 1 is completely accommodated in the hole 31 of the column 3 and the recess 41 of the beam 4. The downward opening is almost completely hidden except that the upper and lower edges of the metal fitting body 1 are partially exposed. And in the joint structure X of the shaft set in this state, the movement of the beam 4 with respect to the connection fitting 1 in the drawing direction is performed by the drift pin 2 firmly fixed to the column 3 and the beam 4 in a direction orthogonal to those directions. Be regulated. For this reason, this joining structure X has an extremely high tensile strength, and a very stable joining structure X can be configured. Further, since the drift pin main body 21 and the engaging member 22 are both embedded in the pillar 3 and the beam 4, the drift pin does not protrude from the surface of the pillar 3 or the beam 4, so that the shaft assembly is finished. It's beautiful.

  As described above, the drift pin 2 of the present embodiment is joined by engaging the connecting fitting 1 in which the pillar 3 made of wood and the beam 4 as the horizontal member are interposed therebetween. If used in a wooden frame structure that is used and fixed in the joint structure X, which is a wooden frame structure, the locking holes 32, 33, 42, 43 formed in the pillar 3 and the beam 4 and connection fittings corresponding to them are provided. The drift pin body 21 is inserted into the through holes 16A6b and 17A7b formed in FIG. It is possible to expand and contract between an initial state smaller than the inner diameter of the through holes 16a, 16b, 17a, and 17b formed in the connection fitting 1 and an expanded state that is equal to or larger than the inner diameter of the through holes 16a, 16b, 17a, and 17b. Drift pin body 21 and In the initial state, the engaging holes 32, 33, 42, 43 of the pillar 3 and the beam 4 and the insertion holes 21d of the drift pin body 21 in the state of being inserted into the through holes 16a, 16b, 17a, 17b of the connection fitting 1 are related. It is comprised with the engaging member 22 which can make the drift pin main body 21 an expanded state by combining.

  In the case of the drift pin 2 that can be expanded and contracted in such a configuration, the drift pin body 21 in the initial state is inserted into the locking holes 32, 33, 42, 43 of the column 3 and the beam 4 and the through holes 16A6b, 17A7b of the connection fitting 1. The expanded state is formed by inserting and engaging the engaging member 22 with the insertion port 21d of the drift pin main body 21. And since the drift pin main body 21 can bite into and engage with the through holes 16A6b and 17A7b of the connection fitting 1 due to a large change in the outer diameter of the drift pin main body 21, the connection fitting 1 and the drift pin 2 is firmly fixed, and through that, the structural strength of the entire shaft assembly can be improved. Further, the operation of engaging the drift pin 2 with the connection fitting 1 is performed by engaging the engagement member 22 inside the drift pin main body 21, specifically, the rod-shaped engagement with the insertion hole 21 d formed in the drift pin main body 21. The drift pin body 21 can be simply driven by driving the engagement pin 22 and expanding the opening width of the slit 21c formed in the drift pin body 21 so as to communicate with the insertion hole 21d. Since the entire outer dimensions are expanded, the structure of the drift pin 2 itself can be simplified and the manufacturing cost can be reduced.

  In this case, since the connection fitting 1 and the drift pin 2 are directly fixed, a long time has passed after the construction column 3 and the beam 4 of the shaft assembly are joined and fixed via the connection fitting 1. Thus, even when the pillar 3 and the beam 4 which are timbers are thinned, and the locking holes 32, 33, 43 and 43 where the drift pin 2 is bitten are expanded, the pillar 3 and the beam 4 connecting member 1 are expanded. And the drift pin 2 are not loosened, and it is unlikely that the entire joint structure X is loosened. Therefore, it is possible to obtain a strong wooden framed building that is stable for an extremely long time. Further, when the building is dismantled, it is only necessary to attach another rod-like member to the drift pin 2 that has been driven into the column 3 or the beam 4, so that the column 3, the beam 4, and the connection fitting 1 are hardly damaged. They can also be reused. In addition, since the drift pin 2 is configured by engaging the engagement member 22 inside the insertion hole 21d of the drift pin main body 21, there is no protrusion on the outer peripheral edge of the drift pin main body 21 and simplification is achieved. be able to. Further, when the building or the like is dismantled, the drift pin 2 has a configuration that can be expanded and contracted, and the engagement member 22 is released from the drift pin body 21 by hitting it with a hammer or the like (not shown). It is possible for the drift pin body 21 to return from the expanded state to the initial state. Thereby, joining of the connection metal fitting 1 and the drift pin main body 21 is cancelled | released. Furthermore, it is easy to remove the drift pin main body 21 from the pillar 3 and the beam 4, and it is possible to reuse these timbers without destroying the pillar 3 and the beam 4.

  Further, by forming the slit 21c opened along the longitudinal direction of the drift pin main body 21, the engagement member 22 is engaged with the drift pin main body 21 in the initial state so that the opening width of the slit 21c is widened. By configuring, the drift pin body 21 can be easily expanded, and an insertion hole 21d that opens to the anti-insertion portion 21b of the drift pin body 21 and communicates with the slit 21c is formed. Therefore, the engaging member 22 can be smoothly inserted into and engaged with the insertion hole 21d from the anti-insertion portion 21b, and the engaging member 22 has an outer diameter dimension equal to or larger than the inner diameter dimension of the insertion hole 21d. Since the member has a rod shape, the drift pin body 21 can be easily changed from the initial state to the expanded state.

  The present invention is not limited to the embodiment described above. For example, in order for the drift pin body to form an expanded state from the initial state, a plurality of slits formed in the drift pin body may be formed in the longitudinal direction of the drift pin body. In this case, it is also preferable that the length of the slit is not formed so as to extend over the entire length direction but can be close to the vicinity of the tapered portion formed on the insertion end side. Furthermore, the engaging member for forming the integrated drift pin by being engaged with the insertion hole formed in the drift pin main body forms the expanded state from the initial state and disengages from the connection fitting. The shape is not particularly limited as long as the drift pin body can be in an expanded state so that it does not occur, and is not limited to the above-described shape. For example, a spherical shape, a conical shape, or a suitable shape such as a polygonal shape may be used. In addition, the specific configuration of each part is not limited to the above embodiment, and various modifications can be made without departing from the spirit of the present invention.

The disassembled perspective view which shows the junction structure using the drift pin which concerns on one Embodiment of this invention. The perspective view which shows the drift pin which concerns on this embodiment. FIG. 2A is an end view taken along line AA. The end view which shows the principal part of the BB line end view same figure drift pin to the same (b). The front view which shows the joining structure to which the embodiment is applied. Sectional drawing which fractures | ruptures and shows FIG. 4 by the CC line.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Connection metal fitting 2 ... Drift pin 3 ... Column 4 ... Horizontal member (beam)
16A6b, 17A7b ... through hole 21 ... drift pin body 21b ... anti-insertion end 21c ... slit 21d ... insertion hole 22 ... engagement member 32, 33 ... engagement hole 42,43 ... engagement hole X ... wooden frame structure (joint Construction)

Claims (4)

Used in a wooden frame structure to join a pillar made of wood and a horizontal member such as a beam by engaging a connecting bracket between them, and corresponding to the locking holes formed in the pillar and the horizontal member It is inserted into the through hole formed in the connection fitting,
An initial state in which the maximum length of a line segment connecting two points on the periphery in a cross section perpendicular to the longitudinal direction is made of a metal rod-like member, and the inner diameter of the through hole A predetermined portion inside the drift pin main body that can be expanded / contracted between the expanded state equal to or greater than the same, and the state where the drift pin main body is inserted into the locking hole of the pillar and the horizontal member and the through hole of the connection fitting in the initial state. The drift pin is provided with an engagement member that can bring the drift pin body into the expanded state by being engaged with the drift pin. A slit opened along the longitudinal direction of the drift pin main body is formed, and the drift pin main body is expanded by engaging the engagement member with the drift pin main body in the initial state and widening the opening width of the slit. The drift pin according to claim 1 configured as described above. Forming an insertion hole communicating with the slit by opening the counter pin to the drift pin main body and the locking hole of the horizontal member, and inserting the engagement member into the insertion hole from the counter insertion end, The drift pin according to claim 2, wherein the engaging member is inserted into and engaged with the insertion hole from the side opposite to the insertion end. The drift pin according to claim 3, wherein the engaging member is a rod-shaped member having an outer diameter dimension equal to or larger than an inner diameter dimension of the insertion hole.

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