JP2015059335A - Construction method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To achieve the function of absorbing a construction error of a lower vertical pile.SOLUTION: A construction method includes the steps of: driving a hollow lower vertical pile; inserting a joint member into a hollow part of the lower vertical pile and a regular position of a horizontal plane where the joint member is to be positioned; filling a space between the lower vertical pile and the joint member with a filler for fixing both relative positions; and providing an upper vertical column above the joint member.

Description

  The present invention relates to a construction method.

  A construction method having a step of placing a hollow lower vertical pile and a step of providing an upper vertical column above the lower vertical pile is already well known.

JP-A-4-185841

  Conventionally, when performing such a construction method, the lower vertical pile may be placed at a position shifted from the normal position, and the occurrence of such construction errors has been a problem.

  This invention is made | formed in view of the above conventional problems, The main objective is to implement | achieve the function which absorbs the construction error of a lower vertical pile.

The main present invention is a step of placing a hollow lower vertical pile;
The hollow portion of the lower vertical pile, the step of inserting the joint member into a normal position in the horizontal plane where the joint member should be located,
Filling a filler for fixing both relative positions between the lower vertical pile and the joint member;
Providing an upper vertical column above the joint member;
It is the construction method characterized by having.
Other features of the present invention will become apparent from the description of the present specification and the accompanying drawings.

  According to this invention, the function which absorbs the construction error of a lower vertical pile will be exhibited appropriately.

It is a schematic sectional drawing of the structure 1 which concerns on this Embodiment. It is an image figure for demonstrating the construction error absorption function of the coupling member 40. FIG. It is the figure which showed the procedure of the construction method which concerns on this Embodiment. It is a schematic sectional drawing of the structure 1 which concerns on 2nd embodiment. It is the figure which showed the procedure of the construction method which concerns on 2nd embodiment.

  At least the following will be made clear by the description of the present specification and the accompanying drawings.

Placing a hollow lower vertical pile;
The hollow portion of the lower vertical pile, the step of inserting the joint member into a normal position in the horizontal plane where the joint member should be located,
Filling a filler for fixing both relative positions between the lower vertical pile and the joint member;
Providing an upper vertical column above the joint member;
The construction method characterized by having.
In such a case, the function of absorbing the construction error of the lower vertical pile will be appropriately exhibited.

The joint member includes a first collar part and a second collar part,
In the step of inserting the joint member, the joint member is inserted in a direction such that the first saddle portion is lower than the second saddle portion, and the first saddle portion is inserted into the lowermost vertical pile. Abut the top,
In the step of providing the upper vertical column, the upper vertical column is provided above the second flange,
The method further includes the step of providing a beam member after the step of providing the upper vertical column or in parallel with the step of providing the upper vertical column, and providing a beam member between the first flange and the second flange. It is good.
In such a case, it is possible to perform the installation work of the upper vertical column without waiting for the completion of the installation of the beam member.

Further, the upper vertical column is hollow,
In the step of providing the upper vertical column, the upper vertical column is provided so that the joint member is inserted into a hollow portion of the upper vertical column, and the lowest part of the upper vertical column is applied to the second flange portion. It is good also as making it contact.
In such a case, the joining function is appropriately exhibited in addition to the construction error absorbing function.

And a step of providing a seismic isolation device above the second collar,
In the step of providing the upper vertical column, the upper vertical column may be provided above the seismic isolation device.
In such a case, the seismic isolation function is appropriately exhibited in addition to the construction error absorbing function.

=== About the structure and the construction method according to the present embodiment ===
First, a structure 1 according to the present embodiment and a construction method of the structure 1 will be described with reference to FIGS. 1 to 3. FIG. 1 is a schematic cross-sectional view of the structure 1 according to the present embodiment, and shows a state immediately before the steel pipe upper column 20 is inserted into the joint member 40 as an example. FIG. 2 is an image diagram for explaining the construction error absorbing function of the joint member 40. FIG. 3 is a diagram showing a procedure of the construction method according to the present embodiment.

  The structure 1 includes a steel pipe pile 10 as an example of a lower vertical pile, a steel pipe upper pillar 20 as an example of an upper vertical column, a foundation beam 30 as an example of a beam member, and a joint member 40. Yes.

  The steel pipe pile 10 is a hollow pile (called a pile hollow portion 10a) driven in the ground or the like. As shown in FIG. 1, the steel pipe pile 10 extends in the vertical direction (in other words, the longitudinal direction is along the vertical direction) and has a circular cross section. The cross section of the pile hollow portion 10a is also circular.

  Moreover, the steel pipe pile 10 is equipped with the level adjustment ring 10b in the upper end part. This level adjustment ring 10b is for adjusting (extending) the length of the steel pipe pile 10 by moving upward with respect to the steel pipe pile main body 10c.

  That is, the level adjusting ring 10b is attached to the steel pipe pile main body 10c so as to be slidable in the vertical direction outside the steel pipe pile main body 10c. When it is desired to increase the length of the steel pipe pile 10, the level adjustment ring 10b is slid to a position where the uppermost part of the level adjustment ring 10b is positioned higher than the uppermost part of the steel pipe pile main body 10c. It fixes to the main body 10c by welding. In this way, the length of the steel pipe pile 10 can be extended. And it becomes possible to raise the position in the vertical direction of the steel pipe upper pillar 20, the foundation beam 30, and the coupling member 40 located above the steel pipe pile 10 by this.

  The steel pipe upper column 20 is also a hollow column (referred to as an upper column hollow portion 20a). As shown in FIG. 1, the steel pipe upper column 20 also extends in the vertical direction (in other words, the longitudinal direction is along the vertical direction) and has a circular cross section. In addition, the cross section of the upper column hollow portion 20a is also circular. Moreover, the steel pipe upper column 20 is located above the steel pipe pile 10.

  The joint member 40 is a member that is inserted into the steel pipe pile 10 and the steel pipe upper column 20 (specifically, the pile hollow portion 10a and the upper column hollow portion 20a). The joint member 40 is a CFT member (high strength CFT member). That is, the joint member 40 has a concrete-filled steel pipe structure in which concrete is filled in the steel pipe. Therefore, the joint member 40 is a solid member.

  As shown in FIG. 1, the joint member 40 extends in the vertical direction (in other words, the longitudinal direction is along the vertical direction), and has a main body portion 41 having a circular cross section, and outward from the main body portion 41 ( Two hook portions 42 (in the horizontal direction) extending in a hook shape (circular shape) (the lower hook portion 42 in FIG. 1 is called a first hook portion 43, and the upper hook portion 42 is a second hook portion 45. Called). As shown in FIG. 1, the first flange portion 43 and the second flange portion 45 are provided not at the upper end and the lower end of the joint member 40 in the vertical direction, but at the intermediate portion. Upper body portion 41 a positioned above flange 45, lower body portion 41 b positioned below first flange 43, and intermediate body positioned between first flange 43 and second flange 45 It is divided into a portion 41c.

  The main body portion 41 is a portion that is inserted into the pile hollow portion 10a and the upper column hollow portion 20a. In the present embodiment, the upper main body portion 41a is inserted (inserted) into the upper column hollow portion 20a, and the lower main body portion 41b is inserted (inserted) into the pile hollow portion 10a. Therefore, the outer diameter of the main body portion 41 (the upper main body portion 41a and the lower main body portion 41b) is smaller than the inner diameter of the pile hollow portion 10a and the upper column hollow portion 20a. In the present embodiment, the outer diameter of the upper body portion 41a and the outer diameter of the lower body portion 41b are the same.

  As described above, since the outer diameter of the main body portion 41 of the joint member 40 is smaller than the inner diameter of the hollow portion of the steel pipe pile 10, as shown in FIG. 1, between the joint member 40 and the steel pipe pile 10, There is a gap G. The gap G is filled with a filler 50 such as concrete or epoxy adhesive.

  The joint member 40 exhibits the following functions in cooperation with the filler 50.

  As described above, the steel pipe pile 10 is driven into the ground or the like. At this time, the steel pipe pile 10 is normally placed on the horizontal plane (corresponding to the paper surface in FIG. 2). It may be out of position. That is, as shown in FIG. 2, the regular position of the steel pipe pile 10 (in FIG. 2, the steel pipe pile 10 when the steel pipe pile 10 is located at the regular position is represented by a broken line circle P1 of the center C1) is The steel pipe pile 10 is placed at a position shifted from the position (referred to as an actual placement position. In FIG. 2, the steel pipe pile 10 when it is located at the actual placement position is represented by a solid line circle P2 at the center C2). May be established.

  However, since the gap G described above exists between the joint member 40 and the steel pipe pile 10, when the joint member 40 is inserted into the hollow portion of the steel pipe pile 10, the center C <b> 2 of the placed steel pipe pile 10 is provided. The joint member 40 is not inserted into the steel pipe pile 10 so that the centers C3 of the joint member 40 coincide with each other, but the joint member 40 is slightly shifted from this (in other words, the joint member 40 is eccentric with respect to the steel pipe pile 10). Can be plugged in).

  That is, the joint member 40 is slightly shifted to a normal position on the horizontal plane where the joint member 40 should be positioned (that is, a position where the center C3 of the joint member 40 coincides with the center C1 of the steel pipe pile 10 at the normal position). Can be plugged in. That is, as shown in FIG. 2, the joint member 40 can be inserted into the steel pipe pile 10 such that the center C3 of the joint member 40 coincides with the center C1 of the steel pipe pile 10 at the normal position (in FIG. The joint member 40 to be inserted is represented by a solid line circle P3 having a center C3).

  And it is a hollow part (pile hollow part 10a) of the steel pipe pile 10, and the filler is inserted between the joint member 40 and the steel pipe pile 10 (that is, the gap G) in a state where the joint member 40 is inserted into the regular position. If 50 is filled, both relative positions can be fixed.

  As described above, if the joint member 40 and the filler 50 according to the present embodiment are used, even if the steel pipe pile 10 is driven at a position shifted from the normal position, the joint member 40 can be positioned at the normal position. As a result, the steel pipe upper column 20 provided above the joint member 40 can also be positioned at the normal position. That is, the joint member 40 exhibits a function of absorbing construction errors of the steel pipe pile 10 in cooperation with the filler 50.

  Further, as described above, the joint member 40 according to the present embodiment is inserted not only in the steel pipe pile 10 but also in the steel pipe upper column 20. Therefore, the joint member 40 has not only the construction error absorbing function described above but also a joining function for joining the steel pipe pile 10 and the steel pipe upper column 20.

  Since the joint member 40 is also inserted into the steel pipe upper column 20, the outer diameter of the main body portion 41 of the joint member 40 is smaller than the inner diameter of the hollow portion of the steel pipe upper column 20 as described above. There is also a gap between the joint member 40 and the steel pipe upper column 20. However, since the joint member 40 does not have the above-described construction error absorbing function with respect to the steel pipe upper column 20, this gap is small as can be easily understood from FIG. 1. It is smaller than the gap G. In addition, when the steel pipe upper column 20 is inserted into the joint member 40, the center of the steel pipe upper column 20 is easily aligned with the center C3 of the joint member 40 by making the gap slightly (less than the gap G). Thus, the steel pipe upper column 20 can be easily positioned at the normal position. The gap G between the joint member 40 and the steel pipe pile 10 is filled with the filler 50, while the gap between the joint member 40 and the steel pipe upper column 20 is not necessarily filled with the filler 50. You don't have to. However, from the viewpoint of the bonding function, it is desirable that the filling is performed, and the filling is performed also in the present embodiment.

  When the joint member 40 is inserted into the steel pipe pile 10, the first flange 43 is caught by the steel pipe pile 10 (the level adjusting ring 10 b or the steel pipe pile main body 10 c), so that the joint member 40 passes through the steel pipe pile 10. It plays a role to prevent it. That is, as easily understood from FIG. 1, when the joint member 40 is inserted into the steel pipe pile 10, the first flange portion 43 comes into contact (contact) with the uppermost portion of the steel pipe pile 10 and is caught. It has become. Therefore, the outer diameter of the first flange 43 is larger than the inner diameter of the pile hollow portion 10a. And in this Embodiment, the 1st collar part 43 is located between the steel pipe pile 10 and the foundation beam 30 in the state pinched | interposed into the steel pipe pile 10 and the foundation beam 30 mentioned later.

  When the steel pipe upper column 20 is inserted into the joint member 40, the second flange 45 supports the steel pipe upper column 20 and provides the foundation beam 30 between the steel pipe upper column 20 and the steel pipe pile 10. Play a role in creating space. That is, as easily understood from FIG. 1, when the steel pipe upper column 20 is inserted into the joint member 40, the lowermost part of the steel pipe upper column 20 is caught on the second flange 45. The steel pipe upper column 20 does not go below the second flange 45. Accordingly, a space is created between the steel pipe upper column 20 and the steel pipe pile 10 in the vertical direction (in other words, between the second flange 45 and the first flange 43). It is used as a space for providing.

  In addition, the outer diameter of the second flange 45 is larger than the inner diameter of the upper column hollow portion 20a so that the lowermost portion of the steel pipe upper column 20 is caught by the second flange 45. And in this Embodiment, the 2nd collar part 45 is located between the steel pipe pile 10 and the foundation beam 30 in the state pinched | interposed into the steel pipe upper pillar 20 and the foundation beam 30 mentioned later.

  The foundation beam 30 is a concrete member having a hollow portion (referred to as a foundation beam hollow portion 30a). The foundation beam 30 is provided between the steel pipe upper column 20 and the steel pipe pile 10 in the vertical direction (between the second flange 45 and the first flange 43). In other words, the foundation beam 30 is provided around the aforementioned intermediate main body portion 41 c located between the first flange portion 43 and the second flange portion 45.

  Next, the construction method of the structure 1 which concerns on this Embodiment is demonstrated using FIG.

  First, the worker places a hollow steel pipe pile 10 in the ground or the like (step S1). At this time, the length adjustment ring 10b is slid to adjust the length of the steel pipe pile 10 as necessary.

  Next, the operator inserts the joint member 40 (the lower main body portion 41b) into the hollow portion (pile hollow portion 10a) of the steel pipe pile 10 (step S3). That is, the operator inserts the joint member 40 in a direction such that the first flange 43 is below the second flange 45, and the first flange 43 is placed on the top of the steel pipe pile 10. Contact (insert until the first flange 43 contacts the top of the steel pipe pile 10).

  At this time, the operator inserts the joint member 40 into a normal position on the horizontal plane where the joint member 40 should be located. That is, in this Embodiment, as shown in FIG. 2, the joint member 40 is inserted in the steel pipe pile 10 so that the center C3 of the joint member 40 may correspond with the center C1 of the steel pipe pile 10 of a regular position.

  Next, the operator fills the filler 50 for fixing the relative positions of the steel pipe pile 10 and the joint member 40 (that is, the gap G) (step S5). Any method may be used for filling the filler 50. For example, a filling hole is formed in the first flange 43 in advance, and the filler 50 is poured from the filling hole. do it.

  Next, the worker provides the steel pipe upper column 20 above the joint member 40 (more specifically, above the second flange 45 of the joint member 40). In the present embodiment, the steel pipe upper column 20 is provided so that the joint member 40 is inserted into the hollow portion (upper column hollow portion 20a) of the steel pipe upper column 20, and the lowermost portion of the steel pipe upper column 20 is the second steel plate. It abuts on the part 45. In other words, the hollow portion (upper column hollow portion 20a) of the steel pipe upper column 20 is inserted into the joint member 40 (upper main body portion 41a) until the second flange 45 comes into contact with the uppermost portion of the steel tube upper column 20. (Step S7).

  Next, the worker fills the filler between the steel pipe upper column 20 and the joint member 40 (the gap) in the same manner as the gap G (step S9). Any method may be used for filling the filler. For example, if a hole for filling is opened in the steel pipe upper column 20 in advance, the filler 50 is poured from the hole for filling. Good.

  Next, the operator provides the foundation beam 30 between the steel pipe upper column 20 and the steel pipe pile 10 (between the second flange 45 and the first flange 43) (step S11). That is, the concrete foundation beam 30 is placed in a space (a space around the intermediate main body portion 41c) formed in the meantime.

=== About the structure and construction method according to the second embodiment ===
Next, the structure 1 according to the second embodiment (hereinafter, the already described embodiment is referred to as the first embodiment) and the construction method of the structure 1 will be described with reference to FIGS. 4 and 5. FIG. 4 is a schematic cross-sectional view of the structure 1 according to the second embodiment. FIG. 5 is a diagram showing the procedure of the construction method according to the second embodiment.

  The structure 1 which concerns on 2nd embodiment is also provided with the steel pipe pile 10, the steel pipe upper pillar 20, the foundation beam 30, and the joint member 40 similarly to 1st embodiment. However, unlike the first embodiment, the second embodiment further includes a seismic isolation device 110 (a seismic isolation rubber in the present embodiment).

  This will be specifically described. The structure of the steel pipe pile 10 is the same as the structure of the steel pipe pile 10 according to the first embodiment. That is, the steel pipe pile 10 is a hollow pile (called a pile hollow portion 10a) driven in the ground or the like. As shown in FIG. 4, the steel pipe pile 10 extends in the vertical direction (in other words, the longitudinal direction is along the vertical direction) and has a circular cross section. The cross section of the pile hollow portion 10a is also circular.

  Moreover, the steel pipe pile 10 is equipped with the level adjustment ring 10b in the upper end part. This level adjustment ring 10b is for adjusting (extending) the length of the steel pipe pile 10 by moving upward with respect to the steel pipe pile main body 10c.

  That is, the level adjusting ring 10b is attached to the steel pipe pile main body 10c so as to be slidable in the vertical direction outside the steel pipe pile main body 10c. When it is desired to increase the length of the steel pipe pile 10, the level adjustment ring 10b is slid to a position where the uppermost part of the level adjustment ring 10b is positioned higher than the uppermost part of the steel pipe pile main body 10c. It fixes to the main body 10c by welding. In this way, the length of the steel pipe pile 10 can be extended. And it becomes possible to raise the position in the vertical direction of the steel pipe upper pillar 20, the foundation beam 30, and the coupling member 40 located above the steel pipe pile 10 by this.

  The structure of the steel pipe upper column 20 is the same as the structure of the steel pipe upper column 20 according to the first embodiment. That is, the steel pipe upper column 20 is also a hollow column (referred to as the upper column hollow portion 20a). As shown in FIG. 4, the steel pipe upper column 20 also extends in the vertical direction (in other words, the longitudinal direction is along the vertical direction) and has a circular cross section. In addition, the cross section of the upper column hollow portion 20a is also circular. Moreover, the steel pipe upper column 20 is located above the steel pipe pile 10.

  The joint member 40 is a member inserted into the steel pipe pile 10 (specifically, the pile hollow portion 10a) as in the first embodiment. However, in the second embodiment, unlike the first embodiment, the joint member 40 is not inserted into the steel pipe upper column 20 (specifically, the upper column hollow portion 20a). That is, the joint member 40 according to the second embodiment does not have the above-described joining function of joining the steel pipe pile 10 and the steel pipe upper column 20 (having a construction error absorbing function as described later). .

  This joint member 40 is a CFT member (high-strength CFT member) as in the first embodiment. That is, the joint member 40 has a concrete-filled steel pipe structure in which concrete is filled in the steel pipe. Therefore, the joint member 40 is a solid member.

  As in the first embodiment, as shown in FIG. 4, the joint member 40 extends in the vertical direction (in other words, the longitudinal direction is along the vertical direction) and has a circular main body portion 41 and the section. Two flange portions 42 (in FIG. 4, the lower flange portion 42 in FIG. 4 is referred to as a first flange portion 43) that extends outwardly (in the horizontal direction) from the main body portion 41 (in the horizontal direction). 42 is referred to as a second flange 45).

  In addition, the 1st collar part 43 is provided in the intermediate part instead of the upper end and lower end of the joint member 40 in the perpendicular direction similarly to 1st embodiment. On the other hand, since the joint member 40 according to the second embodiment does not have the joining function as described above, the second flange 45 is provided at the upper end unlike the first embodiment. Therefore, the main body portion 41 is divided into a lower main body portion 41 b positioned below the first flange portion 43 and an intermediate main body portion 41 c positioned between the first flange portion 43 and the second flange portion 45. (There is no upper body portion located above the second flange 45).

  The main body portion 41 is a portion inserted into the pile hollow portion 10a. In the present embodiment, the lower main body portion 41b is inserted into (inserted into) the pile hollow portion 10a. Therefore, the outer diameter of the main body portion 41 (lower main body portion 41b) is smaller than the inner diameter of the pile hollow portion 10a.

  As described above, since the outer diameter of the main body portion 41 of the joint member 40 is smaller than the inner diameter of the hollow portion of the steel pipe pile 10, as shown in FIG. 4, between the joint member 40 and the steel pipe pile 10, There is a gap G. The gap G is filled with a filler 50 such as concrete or an epoxy adhesive as in the first embodiment.

  And the joint member 40 cooperates with this filler 50, and demonstrates a construction error absorption function similarly to 1st embodiment.

  As described above, the steel pipe pile 10 is driven into the ground or the like. However, in this case, the steel pipe pile 10 may deviate from a normal position where the steel pipe pile 10 is to be driven in a horizontal plane. That is, it is not the normal position of the steel pipe pile 10 (in FIG. 2, the steel pipe pile 10 when it is located at the normal position is represented by the broken line circle P1 of the center C1), but the actual placement shifted from the normal position. In some cases, the steel pipe pile 10 is placed at a position (in FIG. 2, the steel pipe pile 10 when it is located at the actual placement position is represented by a solid line circle P2 of the center C2).

  However, since the gap G described above exists between the joint member 40 and the steel pipe pile 10, when the joint member 40 is inserted into the hollow portion of the steel pipe pile 10, the center C <b> 2 of the placed steel pipe pile 10 is provided. The joint member 40 is not inserted into the steel pipe pile 10 so that the centers C3 of the joint member 40 coincide with each other, but the joint member 40 is slightly shifted from this (in other words, the joint member 40 is eccentric with respect to the steel pipe pile 10). Can be plugged in).

  That is, the joint member 40 is slightly shifted to a normal position on the horizontal plane where the joint member 40 should be positioned (that is, a position where the center C3 of the joint member 40 coincides with the center C1 of the steel pipe pile 10 at the normal position). Can be plugged in. That is, as shown in FIG. 2, the joint member 40 can be inserted into the steel pipe pile 10 such that the center C3 of the joint member 40 coincides with the center C1 of the steel pipe pile 10 at the normal position (in FIG. The joint member 40 to be inserted is represented by a solid line circle P3 having a center C3).

  And it is a hollow part (pile hollow part 10a) of the steel pipe pile 10, and the filler is inserted between the joint member 40 and the steel pipe pile 10 (that is, the gap G) in a state where the joint member 40 is inserted into the regular position. If 50 is filled, both relative positions can be fixed.

  As described above, similarly to the first embodiment, if the joint member 40 and the filler 50 according to the second embodiment are used, even if the steel pipe pile 10 is driven at a position shifted from the normal position, the joint member 40 is The steel pipe upper column 20 provided above the joint member 40 can also be positioned at the normal position. That is, the joint member 40 exhibits a function of absorbing construction errors of the steel pipe pile 10 in cooperation with the filler 50.

  Similar to the first embodiment, when the joint member 40 is inserted into the steel pipe pile 10, the first flange portion 43 is hooked on the steel pipe pile 10 (the level adjustment ring 10 b or the steel pipe pile main body 10 c), thereby the joint member 40. Plays a role in preventing the steel pipe pile 10 from slipping through. That is, as easily understood from FIG. 4, when the joint member 40 is inserted into the steel pipe pile 10, the first flange portion 43 comes into contact (contact) with the uppermost portion of the steel pipe pile 10 and is caught. It has become. Therefore, the outer diameter of the first flange 43 is larger than the inner diameter of the pile hollow portion 10a. And in this Embodiment, the 1st collar part 43 is located between the steel pipe pile 10 and the foundation beam 30 in the state pinched | interposed into the steel pipe pile 10 and the foundation beam 30 mentioned later.

  The second flange 45 supports the seismic isolation device 110 and plays a role of creating a space for providing the foundation beam 30 between the seismic isolation device 110 and the steel pipe pile 10. That is, as can be easily understood from FIG. 4, when the seismic isolation device 110 is supported by the second collar portion 45, the seismic isolation device 110 does not go below the second collar portion 45. It has become. Therefore, a space is created between the seismic isolation device 110 and the steel pipe pile 10 in the vertical direction (in other words, between the second flange portion 45 and the first flange portion 43). It is used as a space for providing. The second flange 45 is located between the base isolation device 110 and the foundation beam 30 while being sandwiched between the base isolation device 110 and the foundation beam 30.

  The seismic isolation device 110 is provided above the second flange 45, and the steel pipe upper column 20 is provided above the seismic isolation device 110. That is, the seismic isolation device 110 is located between the second flange 45 and the steel pipe upper column 20 in the vertical direction. In the present embodiment, the seismic isolation device 110 is joined to each of the second flange 45 and the steel pipe upper column 20 by bolt joining.

  As in the first embodiment, the foundation beam 30 is a concrete member having a hollow portion (referred to as a foundation beam hollow portion 30a). The foundation beam 30 is provided between the seismic isolation device 110 and the steel pipe pile 10 in the vertical direction (between the second flange 45 and the first flange 43). In other words, the foundation beam 30 is provided around the aforementioned intermediate main body portion 41 c located between the first flange portion 43 and the second flange portion 45.

  Next, the construction method of the structure 1 which concerns on 2nd embodiment is demonstrated using FIG.

  First, the worker places a hollow steel pipe pile 10 in the ground or the like (step S101). At this time, the length adjustment ring 10b is slid to adjust the length of the steel pipe pile 10 as necessary.

  Next, the operator inserts the joint member 40 (the lower main body portion 41b) into the hollow portion (pile hollow portion 10a) of the steel pipe pile 10 (step S103). That is, the operator inserts the joint member 40 in a direction such that the first flange 43 is below the second flange 45, and the first flange 43 is placed on the top of the steel pipe pile 10. Contact (insert until the first flange 43 contacts the top of the steel pipe pile 10).

  At this time, the operator inserts the joint member 40 into a normal position on the horizontal plane where the joint member 40 should be located. That is, in this Embodiment, as shown in FIG. 2, the joint member 40 is inserted in the steel pipe pile 10 so that the center C3 of the joint member 40 may correspond with the center C1 of the steel pipe pile 10 of a regular position.

  Next, the operator fills the filler 50 for fixing the relative positions of the steel pipe pile 10 and the joint member 40 (that is, the gap G) (step S105). Any method may be used for filling the filler 50. For example, a filling hole is formed in the first flange 43 in advance, and the filler 50 is poured from the filling hole. do it.

  Next, the operator installs the seismic isolation device 110 above the joint member 40 (on the second flange 45) (step S107). In the present embodiment, the seismic isolation device 110 is installed on the second flange 45 by bolt joining.

  Next, an operator provides the steel pipe upper column 20 above the joint member 40 (the second flange 45) (more specifically, above the seismic isolation device 110) (step S109). In the present embodiment, the steel pipe upper column 20 is installed on the seismic isolation device 110 by bolt joining.

  Next, the worker provides the foundation beam 30 between the seismic isolation device 110 and the steel pipe pile 10 (between the second flange 45 and the first flange 43) (step S111). That is, the concrete foundation beam 30 is placed in a space (a space around the intermediate main body portion 41c) formed in the meantime.

=== About the effectiveness of the construction method according to the above embodiment ===
As above-mentioned, the construction method which concerns on the said embodiment (1st and 2nd embodiment) is the step which drives the hollow steel pipe pile 10, and the hollow part of the steel pipe pile 10, Comprising: The joint member 40 is a position. A step of inserting the joint member 40 into a normal position in the horizontal plane to be filled, a step of filling a filler 50 for fixing the relative position between the steel pipe pile 10 and the joint member 40, and the steel pipe upper column 20 And a step provided above the member 40.

  Therefore, the function which absorbs the construction error of the steel pipe pile 10 will be exhibited appropriately as described above.

  Moreover, in the said embodiment, the said joint member 40 is provided with the 1st collar part 43 and the 2nd collar part 45, and in the step which inserts the joint member 40, the 1st collar part 43 is the joint member 40. In the step of inserting the steel plate upper pillar 20 by bringing the first steel plate portion 43 into contact with the uppermost portion of the steel pipe pile 10 in a direction that is lower than the second steel plate portion 45, the second steel plate portion 20 is provided. The steel pipe upper column 20 is provided above 45, and the steel pipe upper column 20 is provided after the step of providing the steel beam upper column 20, and further includes the step of providing the foundation beam 30 between the first flange part 43 and the second flange part 45. .

  As a result, the restriction that the construction work is performed in order from the bottom, that is, the restriction that the work for providing the upper steel pipe column 20 is performed after the foundation beam 30 is provided is released. That is, the installation work of the steel pipe upper column 20 can be performed without waiting for the completion of the installation of the foundation beam 30.

  In the first embodiment, the steel pipe upper column 20 is hollow, and in the step of providing the steel pipe upper column 20, the steel pipe upper column 20 is provided so that the joint member 40 is inserted into the hollow part of the steel pipe upper column 20, In addition, the lowermost portion of the steel pipe upper column 20 is brought into contact with the second flange 45.

  Therefore, in the first embodiment, as described above, the joining function is appropriately exhibited in addition to the construction error absorbing function.

  Moreover, in 2nd embodiment, it has the step which provides the seismic isolation apparatus 110 above the 2nd collar part 45, and in the step which provides the steel pipe upper pillar 20, the steel pipe upper pillar 20 is provided above the seismic isolation apparatus 110. We decided to provide it.

  Therefore, in the second embodiment, the seismic isolation function is appropriately exhibited in addition to the construction error absorbing function.

=== Other Embodiments ===
The above embodiments are for facilitating the understanding of the present invention, and are not intended to limit the present invention. The present invention can be changed and improved without departing from the gist thereof, and it is needless to say that the present invention includes equivalents thereof. In particular, the embodiments described below are also included in the present invention.

  In the said embodiment, although the steel pipe pile 10 was mentioned as an example and demonstrated as a lower vertical pile, it is not limited to this. For example, it may be a PHC pile.

  In the above embodiment, the step of providing the foundation beam 30 between the first flange portion 43 and the second flange portion 45 is executed after the step of providing the steel pipe upper column 20. It may be executed in parallel with the step of providing the column 20.

  And even in such a case, it is released from the restriction that the construction work is performed in order from the bottom, that is, the restriction that the work of providing the steel pipe upper column 20 is performed after the foundation beam 30 is provided. It will be. That is, the installation work of the steel pipe upper column 20 can be performed without waiting for the completion of the installation of the foundation beam 30.

DESCRIPTION OF SYMBOLS 1 Structure 10 Steel pipe pile 10a Pile hollow part 10b Level adjustment ring 10c Steel pipe pile main body 20 Steel pipe upper pillar 20a Upper pillar hollow part 30 Foundation beam 30a Foundation beam hollow part 40 Joint member 41 Main body part 41a Upper main body part 41b Lower main body part 41c Intermediate body portion 42 ridge portion 43 first ridge portion 45 second ridge portion 50 filler 110 seismic isolation device G gap

Claims (4)

Placing a hollow lower vertical pile;
The hollow portion of the lower vertical pile, the step of inserting the joint member into a normal position in the horizontal plane where the joint member should be located,
Filling a filler for fixing both relative positions between the lower vertical pile and the joint member;
Providing an upper vertical column above the joint member;
The construction method characterized by having. In the construction method according to claim 1,
The joint member includes a first collar part and a second collar part,
In the step of inserting the joint member, the joint member is inserted in a direction such that the first saddle portion is lower than the second saddle portion, and the first saddle portion is inserted into the lowermost vertical pile. Abut the top,
In the step of providing the upper vertical column, the upper vertical column is provided above the second flange,
The method further includes the step of providing a beam member after the step of providing the upper vertical column or in parallel with the step of providing the upper vertical column, and providing a beam member between the first flange and the second flange. A construction method characterized by In the construction method according to claim 2,
The upper vertical column is hollow;
In the step of providing the upper vertical column, the upper vertical column is provided so that the joint member is inserted into a hollow portion of the upper vertical column, and the lowest part of the upper vertical column is applied to the second flange portion. A construction method characterized by contact. In the construction method according to claim 2,
Providing a base isolation device above the second collar,
In the step of providing the upper vertical pillar, the upper vertical pillar is provided above the seismic isolation device.

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