JP5571620B2 - How to install a frame with columns - Google Patents

Description

  In the present invention, for example, a gate-shaped frame having a column facing the span direction and a beam erected between both columns is constructed, and the target is installed by sliding it in the direction crossing the span direction. The present invention relates to a method of installing a frame structure with a pillar to be fixed at a position.

  For example, it is constructed from pillars facing in the span direction, beams erected between both pillars, and girders erected between adjacent columns in the column direction and builds structures such as warehouses and factories with a gate-shaped cross section. In this case, because the length in the column direction becomes large, the construction section in the column direction is restricted, for example, it is difficult to build the entire structure at the installation position from the viewpoint of securing the work space in the vicinity. Sometimes. In such a case, as shown in FIG. 11, the entire structure is divided into a plurality of blocks (units) in the column direction, and each time the divided blocks are constructed, the columns are sequentially arranged in the column direction along the rails. The method of moving and completing the whole is used (refer patent documents 1-3).

  The fixing state of the opposing pillars constituting the portal block is the final installation state as shown in FIG. 15- (a), and the fixing is performed in a pin joint state that does not bear a bending moment on the fixing part such as the footing. And the case of fixing in a fixed state as shown in (b).

  When the column is composed of a plurality of column members 21, 22 (31, 32) arranged in parallel in the span direction as shown in FIG. 4- (a) and the column base is fixedly supported, the column is shown in (b). In this way, a vertically upward pulling force acts on the leg portion of the column member on the outside in the span direction due to the weight of the block in the installed state of the column. If you try to move the gate-shaped block while maintaining the state where the outer column member can resist the pulling force, the column base slides along the rail while securing the reaction force against lifting ( Therefore, a resistance mechanism for securing a reaction force during movement becomes large.

  As shown in Fig. 15- (b), when the portal block to which the column base is fixed is in the installed state, the horizontal reaction force, the vertical reaction force, and the bending moment are applied to the column base from the fixing unit (ground). Is in a state of acting. Among these, the horizontal reaction force and the vertical reaction force maintain the state in which the column base is subjected to the reaction force by laying rails that cause the reaction force to act on the column base as shown in FIG. However, in order to maintain a state where the column base receives a bending moment from the rail, the rail must be formed so as to sandwich the base plate of the column base in the vertical direction, for example (see Patent Documents 1 and 2). ). FIG. 16 shows a method of supporting the column base on the rail when resistance against the bending moment of the reaction force at the column base is not ensured.

  In such a case, the base plate of the column base part slides in contact with the bottom surface (upward surface) and the top surface (downward surface) of the rail on the lower surface and the upper surface, so the resistance during sliding (sliding) is large. There is a possibility. In order to reduce the resistance during sliding, it is necessary to interpose a low friction material for reducing the resistance in the contact state (see Patent Document 1), or to avoid contact during sliding (sliding) It is necessary to ensure clearance (see Patent Document 2).

JP-A-8-93059 (Claim 2, paragraphs 0010 to 0011, FIGS. 4 to 8) JP 2010-13870 (Claim 5, paragraphs 0030 to 0033, 0055 to 0061, FIG. 10) JP 2007-284922 A (Claim 1, paragraphs 0027 to 0039, FIGS. 1 to 5)

  However, in both methods of Patent Documents 1 and 2, when the block slides (sliding or sliding), the pulling force acts on the column base portion of the column member on the outside in the span direction, so that the block is running. Since at least one of the bottom surface and the top surface of the base plate (flange) comes into contact with the rail and receives a frictional force, the stability of the column base may be impaired. In this case, for the purpose of reducing the resistance force due to the frictional force that the base plate receives from the rail, a clearance is secured between the upper surface of the base plate and the rail, and the base plate can move relative to the rail within the clearance range. It is difficult to keep the bottom surface of the base plate of the column base in contact with the top surface of the rail (to ensure stability).

  In addition, in order to resist the pulling force of the column base part, as described above, a plate (engagement part) for preventing the lifting from the upper surface of the base plate (flange) and pressing the base plate from above is fixed to the rail. There is a need. In addition, the joint between the engaging portion itself and the rail needs to be strong enough to resist the pulling force, and if the pulling force becomes excessive, the engaging portion may be damaged.

  The present invention is based on the above background. When the column is composed of column members arranged in parallel in the span direction, the column base is fixed at the time of final fixing. In order to ensure stability, the column base is pin-supported during the slide so that no pulling force is generated on the column base, and when it is fixed in place after the slide, the original stress state, that is, the parallel columns The present invention proposes a method for installing a framed structure with columns so that a predetermined stress is generated in a column member outside the span direction among the members.

According to the first aspect of the present invention, there is provided a method for installing a frame structure with a pillar by sliding in a built state a structure having a pillar which is opposed to the span direction and a beam constructed in the span direction between the two columns as a basic element. It is a method of sliding in a direction crossing the direction and fixing the leg portions of the opposing pillars in a fixed state to the fixing portions positioned below the level at the time of sliding at the installation position of the frame body,
At least one of the opposing columns has a column member juxtaposed in the span direction, and the leg portion of any column member that receives a vertically upward force when the at least one column is fixed at the installation position. After sliding the frame to the installation position, with the opposing pillars placed on the track in a state of floating,
Lowering the parallel column member of the one column having the column member in the floated state and fixing the leg portion of the parallel column member to the fixing unit;
The other requirement is to lower the other column opposite the one column and fix the leg portion to the fixing unit.

  The “direction intersecting with the span direction” in claim 1 is intended to include a direction inclined with respect to that direction in addition to the column direction orthogonal to the span direction. “Fixing portion positioned below the level at the time of sliding” is the level of the track (rail) when the bottom surface of the column member (column base), for example, the bottom surface of the base plate is slid along the track (rail), for example, This means that the level of the fixing part is located below the level at the top of the rail, and the pillar member (column base part) is lowered (jacked down) from the rail after sliding (running), so that the foundation (footing) etc. Land on the fixing part. The “track” in claim 1 mainly refers to a rail laid on the ground or in the ground, but can be used as a rail for moving a frame as an upper frame such as a girder in a structure. Also includes material parts. Hereinafter, the “track” is referred to as a rail.

  “At least one of the opposing columns has a column member that is parallel in the span direction” means that at least two column members that are parallel to each other when the column having the parallel column members is finally fixed to the fixing unit. It is fixed (fixed) to the fixing part (columns are rigidly joined), and the column members are aligned in the span direction, so that the bending moment that acts in the span direction (around the horizontal axis in the column direction) It means having the ability to resist. Since it is “at least one of the pillars”, both of the opposing pillars (“one pillar” and “the other pillar” in claim 1) may be composed of parallel pillar members. The “other column” may be only one column member. There may be three or more “parallel column members”. For example, three or four column members may be arranged at the apex positions of a triangle or a quadrangle to form an assembled column.

  “A state in which the leg portion of any column member receiving a vertically upward force in a fixed state is floated” is a column member 31, 32 in which one column 3 of the columns 2, 3 facing each other is arranged in parallel. -In the example of (a), when the block 1A constituting the frame body 1 is running (sliding), the column 3 composed of the column members 31 (B) and 32 (C) arranged in parallel is any one column member. It is supported (contacted) by the rail 5 only at 31 (B), and the other column member 32 (C) is in a state of floating from the rail 5 as shown in FIG. The “vertical upward force” is a pulling force that acts on the leg portion of the column member in a fixing state to the fixing portion. The column member assumed to have the pulling force in the fixed state is placed in a state of floating from the rail level (rail) when the frame body moves (slides). 1 and 2, the level of the lower surface (bottom surface) of each leg 21 a, 31 a, 32 a of the pillar members 21, 31, 32 indicates the level of the rail 5.

  The “column 3 composed of the column members 31 and 32 arranged in parallel” refers to a column that receives a bending moment as a reaction force from the fixing portion (foundation) at the time of final fixing. 2 and 4 show cases where both the columns 2 and 3 and the beam 4 constituting the frame 1 are configured by trusses, but the form (configuration) of the columns 2 and 3 and the beam 4 is arbitrary. is there.

  “Drop the one column having the column member in the floated state” means that the column members 31 and 32 that constitute the “one column 3” are lowered, including the column member in the floated state. Say to let you. “Descent the other column 2 opposite to one column 3” refers to “the other column 2” opposed to “one column 3” having the column members 31 and 32 arranged side by side in advance. This means that the column member 21 is lowered. When the other pillar 2 is also composed of a plurality of parallel pillar members, all the pillar members are lowered.

  In FIG. 2B, one of the column members 31 and 32 (column member 31) arranged in parallel to constitute "one column 3" and the column member 21 that constitutes "other column 2" are attached to the rails 5 and 5. The state when the frame body 1 is slid in the column direction in the supported state is shown. The column members 31 and 32 shown in parallel here are originally supported by the ground or the like (fixing portion) and the frame 1 is formed. Therefore, one column member 32 of the column members 31 and 32 arranged in parallel is the ground. By placing the frame 1 in a floating state, the frame body 1 generates a horizontal displacement δH toward the “other pillar 2” side.

  Although the pillar 3 is composed of a plurality of pillar members 31 and 32 arranged side by side, the pillar 3 (one pillar member 31) is bent by a moment when the pillar 3 is supported by the rail 5 at the time of traveling. It is kept in a state not to receive. When the pillar 2 is composed of one pillar member 21 (A) like the left pillar 2 (“the other pillar”) in FIG. 2A, the one pillar member 21 (A ) Is slid while being supported by the rail 5. In FIG. 2- (b), FIG. 3- (a), (b), the parallel column members 31 and 32 of the “one column 3” referred to in claim 1 are indicated by B and C, and the levels at the lower ends thereof. Are indicated by b and c. Similarly, the column member 21 of “the other column 2” in claim 1 is indicated by A, and the level of the lower end thereof is indicated by a.

  The column 3 that receives a bending moment from the fixing portion at the time of final fixing is slid to the fixing position (installation position) while being supported by the rail 5 in any of the column members 31 (B). In the span direction (the direction in which the column members 31 and 32 are arranged in parallel), the rail 5 is supported by only one of the column members 31 instead of all the column members 31 and 32 arranged in parallel. The column member 31 supported by is maintained in a state of receiving only a vertical upward reaction force from the rail 5. As a result, even though the column 3 is composed of a plurality of column members 31 and 32 arranged side by side, any of the column members has a pulling force as in the case where two or more column members are simultaneously supported by the rail 5. Since the column 3 is not received, the column 3 is kept in a state where only the vertical upward reaction force is received only by the column member 31 (B) located on the rail 5.

  Which of the column members 31 and 32 in parallel is subjected to the pulling force due to its own weight (vertical load) or when a horizontal load is applied is determined by joining the opposing columns to the ground (fixing part) in principle. It depends on the condition. Both the opposing columns are joined (fixed) in a fixed state (rigidly) as shown in FIG. 15- (b), and the other column 2 (column is shown in FIG. 2- (a). When the member 21) is pin-joined and the one column 3 is joined in a fixed state, the column base in the fixed state is positioned on the outer side as described above because the bending moment of the reaction force acting inward acts. A pulling force acts on the column member 32 to be operated. One column 3 composed of the column members 31 and 32 arranged in parallel is joined to the fixing portion of each of the column members 31 and 32 arranged in parallel, and as a result, the column 3 is in a fixed state (rigidly joined state).

  However, when the column 3 is composed of the column members 31 and 32 arranged in parallel, if a pulling force acts on the column base portions 31a and 32a (base plate) of any of the column members 31 (32), the column Regardless of whether or not the member 31 (32) is used, only one of the column members 31 (32) is supported by the rail 5 and the other column member 32 (31) is not supported by the rail 5. In this case, since the vertical upward reaction force acts only on the column member 31 (32) supported by the rail 5, no pulling force acts on the other column member 32 (31).

  The rails 5 for resisting the pulling force as the columns 2 and 3 (column members) are eliminated by not receiving the pulling force when the columns 2 and 3 made of the parallel column members travel on the rail 5. It is not necessary to have a part (flange) for receiving the reaction force from the rail, and the rail 5 does not need to have a part (engaging part) for restraining the flange of the column member. As a result, the structure (shape) of the column base portions 31a and 32a of the column members 31 and 32 and the rail 5 is simplified, and there is a risk that the engagement portion may be damaged when the engagement portion is formed on the rail 5. Avoided.

  As shown in FIG. 4- (a), when each of the columns 2 and 3 facing in the span direction is composed of the column members 21, 22, 31, and 32 arranged in parallel, the column members 21, 22, 31, and 31 arranged in parallel are arranged. If both 32 are placed on the rail, as described above, the outer column members 22 and 32 in the facing direction receive a force to lift from the rail due to their own weight, as shown in FIG.

  In this case, in order to prevent the pulling force from acting on any of the column members arranged in parallel, the inner column member is basically supported by the rail as shown in FIG. This is because only one (inner side) column member among the parallel column members is supported by the rail, so that there is no room for the pulling force to act on the column member. As described above, in the state where the reaction force from the ground to the column members 22 and 32 on the outside in the span direction is downward in the vertical direction in FIG. 4B, the pulling force acts on the column members 22 and 32 on the outside. Is meant to do.

  For example, when a reaction force as shown in FIG. 4B is generated on the bottom surfaces of the parallel column members, the outer column member is released from the support (restraint) to the rail as shown in FIG. If only the pillar member is supported on the rail, a reaction force as shown in FIG. 6 is generated on the bottom surface of the inner pillar member. In FIG. 6, focusing on the left column in which the column members inside the parallel column members are supported by the fulcrum among the opposing columns, the outside not supported by the fulcrum as shown in FIG. The bottom surface of the column member is not restrained from the fulcrum (rail), so that it tends to lift. In this case, it is possible to unify the levels of the bottom surfaces of the parallel column members by forcibly lowering the column members that are lifted after the movement of the frame 1 (block 1A).

  In the case of FIG. 7- (a), for example, the bottom surface of the column member that is likely to be lifted is supported by the rail, while the bottom surface of the column member supported by the rail in FIG. When released, the bottom surface of the pillar member released from the support tends to descend. However, if the bottom surface can be kept in contact with the ground during traveling, the pillar member can be fixed to the fixing portion by jacking up the pillar member that is not supported by the rail after the frame is moved. It is also possible to unify the levels of the bottom surfaces of the column members arranged in parallel.

  Thus, when each of the columns 2 and 3 facing in the span direction is composed of parallel column members, only one of the column members parallel to each other when the frame is running is placed on the rail. By supporting it, it is possible to obtain a state in which no pulling force is applied to any of the column members during traveling, and the bottom surfaces of all the column members can be set to any level including the column members that are likely to lift during final fixing. It can be fixed to the fixing portion.

  The column members 31 and 32 juxtaposed in the span direction are both joined (fixed) to the fixing unit in a fixed state at the time of final fixing, and at that time, the bottom surfaces (base plate bottom surfaces) of both (all) column members 31 and 32 are on the same horizontal plane. To position. Alternatively, when the levels of the fixing portions are different, they are located on horizontal planes parallel to each other, and the bottom surfaces of both column members are parallel to each other (the angle between the bottom surfaces is 0 degree). On the other hand, as shown in FIG. 2B, the bottom surface of the column member 32 (C) that is lifted from the rail level (rail 5) is supported (contacted) by the rail 5. An angle θ is generated between the column member 31 (B) and the bottom surface of the column base portion 31 a due to relative rotation accompanying lifting when viewed in the column direction.

  Specifically, as shown in FIG. 2B, the bottom surface (contact surface with the rail) of the column member 31 (B) (column base 31a) that is supported by the rail 5 is lifted. Between the straight line (plane) passing through the bottom surface of the column member 32 (C) (column base portion 32 a) and the horizontal surface, an angle θ is created counterclockwise on the elevation surface (cross section). There is a level difference δ (the amount by which the column member 32 (C) is lifted) corresponding to the distance L2 and the angle θ. When the column member 32 (C) that has been lifted before the final fixing is lowered (jacked down), the column member 31 (B) supported by the rail 5 rotates in the reverse direction by this angle θ ( The relative rotation state is canceled by being rotated clockwise. θ and δ are in a relationship of θ (tan θ) = δ / L2, where L2 is the distance between the centers of the column members 31 and 32 in parallel on the horizontal cross section.

  FIG. 2- (a) shows the traveling of the frame 1 composed of two column members 31, 32 (B, C) in which “one column 3” is arranged in parallel as schematically shown in FIG. 2- (b). The relationship between the column members 31 and 32 and the rails 5 and 5 in parallel at the time is shown. Here, the case where the “other pillar 2” is composed of one pillar member 21 (A) is shown, but the “other pillar 2” is also composed of a plurality of pillar members 21 and 22, as shown in FIG. Sometimes. In the state shown in FIG. 2B, the bottom surface of the column member 21 (A) constituting the “other pillar 2” and the bottom surface of the pillar member 31 (B) constituting the “one pillar 3” are both Since it is placed on the rails 5 and 5 laid on the side of the rail, it is located on the same horizontal plane.

  In FIG. 2- (b), the column members 21 and 31 located inside the frame 1 are placed on the rails 5 and 5, and the column member 32 located outside is not supported by anything (floating in the air). It shows how it is in the state. The “rail level (slide level)” in FIG. 2B indicates the upper surface (top end) of the rail 5, and the lower surfaces (base plate of the base plate) when the frame body 1 is slid (runs). This refers to the level of the lower surface. When the lower end (bottom surface) of one column member 31 is positioned on the rail 5 among the parallel column members 31 and 32, the lower end (bottom surface) of the other column member 32 is from the upper surface (rail level) of the rail 5. The above δ is located above. “Fixing level” in FIG. 3 indicates the upper surface (top edge) of the fixing unit.

  When the lower end (bottom surface) of one column member 31 (column base portion 31a) is positioned on the rail 5 among the parallel column members 31 and 32 constituting the "one column 3", the above-described FIG. As shown in (a) and (b), the lower end (bottom surface) of the other column member 32 (column base 32a) is in a state of floating from the ground surface or the like when the block 1A of the frame 1 is moving. It does not matter whether it is in a state of being lowered from the level of the rail 5 or not. Since the bottom surfaces of the column members 31 and 32 finally arranged in parallel only need to land on the respective fixing portions, both the bottom surfaces do not necessarily have to be located in the same horizontal plane.

  As shown in FIG. 3A, the “assumed level” shown in FIG. 3 includes the leg portion 31a (bottom surface) of the column member 31 (B) supported by the rail 5 and the column in which the displacement of δ is generated. When the legs 32a (bottom surface) of the member 32 (C) are both lowered (jacked down) to the “fixing level”, the bottom surface of the column member 21 (A) and the bottom surface of the column member 31 (B) are flush with each other. The level assumed in the leg part 21a (bottom surface) of the other pillar member 21 (A) when it assumes that it is located on the top.

  This level ("assumed level") assumes that the bottom surface of the column member 21 (A) and the bottom surface of the column member 31 (B) are located on the same plane inclined with respect to the horizontal plane, and the bottom surface of the column member 31 (B). And the pillar member 32 (C) are assumed to be located on the same horizontal plane, and the bottom face of the pillar member 31 (B) and the pillar are assumed to be located on the pillar member 21 (A). The height Δ (H−h) from the horizontal plane including the bottom surface of the member 32 (C) is indicated. As shown in FIG. 1, “H” is a level from the level (“fixing level”) at which the bottom surfaces of the column members 21, 31, and 32 are positioned at the time of final fixing of the column members 21, 31, 32 to the above “rail level”. “H” represents the height from the “assumed level” to the “rail level”.

  This height Δ is also the distance between a straight line passing through the points b and c and the point a in FIG. 2B, and the distance between the points b and a is L1, and the horizontal plane of the line segment bc. And θ (tan θ) = Δ / L1, so that Δ = θ · L1. Since θ = δ / L2 as described above, it can be expressed as Δ = L1 / L2 · δ.

  In the equation Δ = L1 / L2 · δ, the column member 21 can be obtained by calculating in advance the amount of lift δ of the bottom surface of the column member 32 in which the column member 32 is lifted by the extraction force from the assumed extraction force by analysis of the frame 1. From the distance L1 between the center of (A) and the center of the column member 31 (B) and the distance L2 between the center of the column member 31 (B) and the center of the column member 32 (C), “fixing level” ”To“ assumed level ”means that the height Δ (H−h) can be obtained.

  Further, since δ is the amount of lift of the bottom surface of the column member 32 that is lifted by the pulling force, as shown in FIGS. 3B, 1C, and 1D, the lift amount δ is set at the time of final fixing. By fixing the column member 32 to the fixing portion in the zero state, the pulling force originally generated in the fixed state is applied to the column base portion 32a of the column member 32, and the column member 32 is counteracted by the column members 31 and 32 arranged in parallel. It is possible to keep the state in resistance to the bending moment of force.

  From the state in which the bottom surface (base plate) of the column member 31 (B) and the bottom surface (base plate) of the column member 32 (C) are respectively fixed to the fixing unit in the same horizontal plane as shown in FIG. By lowering (jacking down) the bottom surface (base plate) of the member 21 (A), the bottom surface (base plate) of the column member 21 (A) becomes the column members 31 and 32 (B) as shown in FIG. , C) can be landed on the fixing portion in the same plane. In this state, the bottom surface (base plate) of the column member 21 (A) is fixed to the fixing unit. The bottom surfaces of the column members 31 and 32 (B, C) and the bottom surface of the column member 21 (A) are tightly connected to the anchor 13 shown in FIG. 9 such as an anchor bolt or a ground anchor fixed in the ground or in the foundation. To be fixed.

  Here, before the column members 31 and 32 (B, C) arranged in parallel with one column 3 are lowered (landed) to the respective fixing portions, as shown in FIG. When the column members 31 and 32 (B, C) arranged in parallel land on the respective fixing portions, up to a level where the bottom surface of the column member 21 (A) constituting the other column 2 is located (the above “assumed level”) If the frame 1 is lowered all at once or uniformly (Claim 2), the other column member 2 (A) is assumed to be inside the frame 1 assumed when the other pillar member 2 (A) remains at the level of the rail 5. It is possible to avoid the generation of stress such as axial force and bending moment.

  As shown in FIG. 3A, when the column members 31 and 32 (B, C) arranged in parallel with one column 3 land on the respective fixing portions, the other column 2 (column member 21 on the side facing it). (A)) tries to descend to the “assumed level” as described above so as to be dragged by the column members 31 and 32 as a part of the frame 1. At this time, if the other column 2 (column member 21) is placed at the "rail level", the column 2 constituting the frame 1 is forced to stay at a level other than the original level. , 3 and the beam 4 may cause stress such as axial force and bending moment.

  Therefore, as shown in FIGS. 1- (a) and (b), before lowering (landing) the column members 31, 32 (B, C) in parallel with one column 3 to the fixing portion, the other column 2 If the frame bodies 1 are lowered all at once or uniformly to a level (an “assumed level”) at which the bottom surface of the column member 21 (A) constituting the frame is located (Claim 2), 1 is not forcedly deformed, it is possible to avoid a situation in which stress such as an axial force or a bending moment is generated inside the columns 2 and 3 and the beam 4 constituting the frame 1. .

  At least one of the opposing columns has a column member that is parallel in the span direction, and the leg of any column member that receives a vertical upward force in a fixed state at the installation position of the one column is floated In this state, with the opposite pillar placed on the track, slide it to the installation position, lower the pillar member in the floated state and fix it to the fixing unit, and then attach the other pillar facing one pillar. Since the leg portion is fixed to the fixing portion by lowering, the column member supported by the rail can be maintained in a state where only the vertical upward reaction force is received from the rail.

  As a result, one of the column members is not subjected to the pulling force as in the case where two or more column members are supported by the rail at the same time, although the column is composed of a plurality of column members arranged in parallel. The pillar can be kept in a state of receiving only the vertical upward reaction force only by the pillar member located on the rail. Therefore, when sliding the frame (block), the column base is pin-supported so that no pulling force is generated on the column base, but when it is fixed at the predetermined (fixing section) position after the slide, the stress state should be That is, a predetermined stress can be generated in the column members on the outside in the span direction among the parallel column members.

  In addition, since the pillars that run on the rail do not receive the pulling force, the pillar (column member) does not need to have a part (flange) that receives the reaction force from the rail to resist the pulling force. Need not have a part (engagement part) for restraining the flange of the column member. As a result, the structure (shape) of the column base and the rail of the column member is simplified, and the risk of causing damage to the engaging portion when the engaging portion is formed on the rail is also avoided.

(A) to (d) are composed of two column members in which one column is arranged in parallel, and the other column is opposed to the block 1A of the frame composed of one column member. It is the elevation which showed the procedure of construction until it moves to an installation position in the state supported by the rail in the inner pillar member, and fixes each pillar member to a fixing part. (A) is a case where one of the opposing pillars is joined to the ground or the like (fixing portion) in a fixed state, and the other pillar is joined by pin joining, from a plurality of pillar members juxtaposing one pillar. Elevated view showing the constructed frame, (b) is one in which the column members constituting one column in the frame shown in (a) and the column member constituting the other column are supported on the rail. FIG. 6 is an elevational view showing a state when the frame is slid in the column direction in the above state. (A) shows the state of all column members when the column member in the floating state in FIG. 2- (b) is lowered (jacked down) after sliding of the frame in the state of FIG. 2- (b). Elevated view showing the level of the bottom surface (base plate), (b) is the entire column when the other column (column member) in FIG. 2- (b) is further lowered (jacked down) from the state of (a). It is the elevation which showed the level of the bottom face (base plate) of a member. (A) A structure composed of a plurality of column members in which both columns are arranged in parallel when both columns on opposite sides are joined (fixed) to the ground or the like (fixing part) in a fixed state (rigidly). The elevation which showed the body (block), (b) is the reaction force figure which showed the reaction force which acts on the column member shown to (a). (A) is the perspective view which showed the reaction force which each column base receives from a rail, when sliding a plurality of blocks of a frame of the section shown in Drawing 4 (b) along a rail (fulcrum), (B) is the perspective view which showed a mode when one column member is supported by a rail (fulcrum) among the column members arranged in parallel, and is slid. Elevated surface showing the reaction force that the column base of the column member receives from the fulcrum (rail) when one of the parallel column members in the frame shown in FIG. 5- (b) is supported by the fulcrum (rail) FIG. (A) is an enlarged view of FIG. 6 showing a state when it is assumed that the column member not supported by the fulcrum is lifted when the column member is supported as shown in FIG. 6, and (b) is (a). FIG. 6 is an elevational view showing a state in which it is assumed that a column member not supported by the fulcrum is supported by the rail and that the support of the column member supported by the fulcrum is released (not supported). It is the perspective view which showed the mode when the pillar member supported by a rail was temporarily supported by a bundle pillar, and the jack was interposed between the support plate and the rail which protruded from the side surface of the pillar member. FIG. 9 is a perspective view showing a state where a carriage (sliding device) is interposed between the support plate and the rail instead of the jack in FIG. 8 or together with the jack. It is the perspective view which showed a mode when moving the pillar member supported by the rail via the trolley | bogie (sliding apparatus) by traction. (A) is an elevational view showing a state in which a plurality of pillar members that are arranged on one rail and constitute one block of the frame are connected to each other by a connecting member, and (b) is (a). FIG. (A) is an elevational view showing a state in which only the carriage is arranged under the bracket of one pillar member in FIG. 11, and (b) is a cross-sectional view in the rail axial direction of (a). (A) is an elevational view showing a state in which only a jack is disposed under a bracket of one pillar member in FIG. 11, and (b) is a cross-sectional view in the rail axial direction of (a). It is the perspective view which showed the point (outline | summary) of the method of moving (sliding) the block of the frame-like structure which has a gate shape shape along a rail. (A) is a reaction force diagram showing the reaction force of the column base when the column of the gate-shaped frame is pin-joined to the ground, etc., (b) is the reaction of the column base when the column is rigidly joined. It is a reaction force diagram showing reaction force. FIG. 15 is an elevational view showing a conventional method for securing a horizontal reaction force and a vertical reaction force in the movement method shown in FIG. 14.

  Hereinafter, the best mode for carrying out the present invention will be described with reference to the drawings.

  FIG. 1- (a) shows the pillars 2 and 3 facing in the span direction and the beam 4 constructed in the span direction between the pillars 2 and 3 as basic elements, and is installed by the slide shown in (b) to (d). The elevation of the structural example of the frame 1 used by the method is shown. Among the opposing columns 2 and 3 of the frame 1, at least one of the columns 3 has column members 31 and 32 arranged in the span direction, and the other column 2 is one as shown in FIGS. 1 and 2. The column member 21 may be composed of only the column member 21, or the column member 21, 22 may be disposed in parallel with the column 3 as shown in FIG. 4.

  1- (b) to (d) slide the frame 1 shown in FIG. 1- (a), or the block 1A in a form obtained by dividing the frame 1 in the sliding direction, in the construction state and in a direction crossing the span direction. The outline of the method of fixing the leg portions of the columns 2 and 3 facing each other at the installation position of the frame 1 (block 1A) to each fixing portion positioned below the level of the slide (rail 5) in a fixed state is shown. An axial elevation of the rail 5 is shown.

  The movement (slide) from the construction position to the installation position of the frame 1 is any column member 32 that receives a vertically upward force in a fixed state at the installation position of at least one column 3 of the frame 1 (block 1A). In a state where the legs of (31) are floated, the frame 1 (block 1A) is slid to the installation position while the opposing columns 2 and 3 are placed on the track (rail 5) and then floated. The column members 31, 32 of the one column 3 having the column member 32 (31) in parallel are lowered, and the leg portions 31 a, 32 a of the column members 31, 32 are fixed to the fixing unit such as the foundation 14. It is done in the way of letting. Thereafter, the column member 21 of the other column 2 facing the one column 3 is lowered to fix the leg portion 21a to the fixing unit.

  Although FIG. 1- (a) shows an example in which one of the columns 2 and 3 facing each other is composed of a plurality of column members 31 and 32 arranged in parallel in the span direction, FIG. As shown in FIG. 6, both pillars 2 and 3 on both sides may be composed of a plurality of pillar members arranged in parallel.

  FIG. 1- (a) shows a block 1A, which is a construction unit constituting the vertical frame 1 shown in FIG. 2- (a), along the rails 5, 5 laid under the pillars 2, 3. The level of the bottom surface of each of the column members 21, 31, 32 when being moved (sliding) is shown. In FIG. 1- (a) to (d), the fulcrum marks indicate the levels of the bottom surfaces of the column base portions 21a, 31a, and 32a. The state where the column members 21 and 31 are supported by the rails 5 and 5 shown in FIG. 1A is also the state shown in FIG. In FIG. 2- (b), the fulcrum marks indicate the levels of the rails 5 and 5.

  In FIG. 1 to FIG. 3, of the opposing pillars 2 and 3, one pillar 3 is composed of a plurality of pillar members 31 and 32 arranged in parallel in the span direction, and the other pillar 2 is composed of one pillar member 21. In this case, the column member 31 on the inner side in the span direction of the one column 3 and the column member 21 of the other column 2 are placed on the rails 5 and 5 and supported. Yes. When either one of the pillars 3 or the other pillar 2 is composed of a plurality of pillar members, any pillar member 31 (32) supported by the rail 5 does not need to be inside in the span direction. In some cases, the column member 32 may be on the outside in the span direction.

  The rail 5 is a column member to be supported by the rail 5, in the drawing, linearly below the column members 21 and 31 on the inner side in the span direction, such as in the crossing direction, such as in the direction of the span, and at the installation position of the frame 1 Will be laid. The frame 1 moved to the installation position is jacked down from the rails 5 and 5 so as to be placed on the ground or the fixing portion installed on the foundation 14 shown in FIG. As shown, it is fixed to the ground at the fixing portion position or the anchor 13 fixed (embedded) on the foundation 14.

  The fixing portion to which the leg portions 21a, 31a, 32a of the column members 21, 31, 32 are fixed may be the foundation 14. As shown in FIGS. 12 and 13, when the foundation 14 is continuously built along the rail 5 below the rail 5, a part of the continuous foundation 14 becomes a fixing portion.

  1 (a) and 2 (b), the one pillar 3 is composed of a plurality of pillar members 31 and 32, but is supported by the rail 5 with one pillar member 31. As a result, the bottom surfaces of the remaining column members 32 that are not supported by the rail 5 are in a state of floating from the ground or the like.

  Here, from the state where the bottom surfaces of the column members 31 and 32 arranged in parallel are in the same horizontal plane as shown in FIG. 2- (b), the bottom surface of the column member 32 that is lifted is rotated counterclockwise from the horizontal plane. The assumed rotation angle is θ. On the other hand, the distance between the centers of the column members 21 and 31 supported by the rails 5 and 5 is L1, the distance between the centers of the column members 31 and 32 arranged in parallel is L2, and the rail on the bottom surface of the column member 32 that is lifted up. If the height from the top end is δ, θ = δ / L2, and therefore the bottom surface of the column member 32 is lifted from the top end of the rail 5 by δ = L2 · θ.

  The frame 1 or the block 1A is moved to the installation position while maintaining the state shown in FIGS. 1- (a) and 2- (b). To move (slide) the frame 1 (block 1A), the column members 21 and 32 of the columns 2 and 3 to be supported by the opposing rails 5 and 5 are placed on the rail 5, and the frame 1 (block 1A), a sliding device (trolley 10 to be described later) for reducing the resistance received by the bottom surface of the column base portions 21a and 31a from the rail 5 and smoothly moving the frame 1 (block 1A). For example, the sliding device is pulled from the installation position side while being interposed between the rail 5 and the rail 5.

  Between the column base portions 21a, 31a of the column members 21, 31 and the rail 5, together with a sliding device (cart 10) as shown in FIG. 11, for jacking down the column members 21, 31, 32 after the movement is completed. The jack 11 may be interposed. 9 and 12 show the situation around the column members 21 and 32 in which only the sliding device (cart 10) is interposed around the column members 21 and 32, and FIGS. 8 and 13 show the columns in which only the jack 11 is interposed. The situation around the members 21 and 32 is shown. The sliding device (cart 10) is attached to one frame structure 1 (block 1A), and may be arranged in a sufficient number to move while supporting the frame structure 1 (block 1A) during the movement. There is no need to be placed under 21,31.

  As the sliding device, a sliding bearing or a rolling bearing (roller) as shown in FIGS. 9 and 11 is mainly used. The sliding device is arranged to move the column base 31a of the column member 31 on the rail 5, and the jack 11 is arranged to lower the column member 31 at the target installation position. As shown in FIG. 1 (Block 1A) is installed at the time of construction. The rail 5 is removably assembled on the ground or on a leveling material 15 such as concrete or mortar laid on the foundation 14 as shown in FIGS. 12 and 13 to move the frame 1 (block 1A). Will be dismantled and removed at the end of.

  In the drawing, as a specific rolling support, a structure (column members 21 and 31) is placed, a loading plate 10a that supports the structure, side plates 10b and 10b that are integrated on both sides in the width direction, and a side plate 10b. , 10b, a horizontal plate 10c installed horizontally, a chain 10d circulated around the horizontal plate 10c, and a roller 10e supported on the shaft of the chain 10d and rolling on the rail 5. An off-the-shelf carriage 10 having a structure is used.

  The carriage 10 travels on the rail 5 as the chain 10d circulates while the roller 10e rolls on the rail 5 in a crawler (infinite track) type. When the column members 21 and 31 are supported by the carriage 10, the carriage 10 receives a tensile force from the movement destination side by the pulling wire 12 or the like, or is pushed from the rear in the movement direction by a hydraulic cylinder (actuator) or the like. Moved.

  The pillar members 21 and 31 placed on the rail 5 are constructed (installed) on the rail 5 from the start of construction of the pillars 2 and 3 including the pillar members and the frame 1 (block 1A), and are shown in FIG. As described above, the base plate 31b of the column base portions 21a and 31a is floated from the top of the rail 5 in order to secure a space for installing (inserting) the carriage 10 between the top of the rail 5 at the time of construction. Temporarily supported by the bundle pillar 6. The bundle pillar 6 is installed on the mortar 61 laid on the ground or on the foundation 14, for example.

  One rail 5 supports one of the frame body 1 (block 1A) or a plurality of column members 31 and 31 (21, 21) arranged in the axial direction of the rail 5. The plurality of column members 31, 31 arranged in the axial direction are connected to each other by a connecting member 33 as shown in FIGS. 9 and 11 and are moved in a connected state.

  After the movement of the frame 1 (block 1A), the base plate 31b of the column member 31 (21) is fixed to the fixing portion at the installation position. Therefore, when the frame 1 (block 1A) is moved, portions other than the base plate 31b Since the frame 1 (block 1A) needs to be supported by the carriage 10 on the rail 5 side surface of the column member 31 (21), the carriage 10 is interposed between the frame 1 (block 1A) and the rail 5. A bracket 7 for projecting is inserted. A support plate 8 for mounting the block 1 </ b> A including the column member 31 (21) on the carriage 10 or the jack 11 is joined (projected) to the bottom surface of the bracket 7.

  After the frame body 1 (block 1A) is moved to the target position by traveling of the carriage 10, the jack 11 inserted between the support plate 8 and the rail 5 or between the ground (base 14) is mounted on the fixing portion. However, the frame 1 (block 1A) is once raised by the jack 11 in order to secure a space for disassembling and removing the rail 5 when it is lowered onto the fixing portion. The jack 11 interposed between the support plate 8 and the rail 5 and the like is mounted on the carriage 10 of the column member 31 and lowered (jack down) at the final installation position, as well as the column member 31 (base plate 31b). Therefore, it is desirable that the jack 11 is disposed below the support plate 8 until the fixing of the column member 31 is completed.

  In order to prevent the column member 31 (21) from being detached (disengaged) from the rail 5 on both sides of the column member 31 (21) in the direction orthogonal to the axial direction of the rail 5 The guide member 9 is joined, and the stability of the column member 31 against the separation from the rail 5 is ensured. The guide members 9 are arranged on both sides of the rail 5 in the width direction so that the column members 31 do not fall on either side in the width direction of the rail 5.

  When the frame 1 (block 1A) is moved by towing with the pulling wire 12, the pulling wire 12 is attached to the bracket 7 of the column member 31 (21) located on the front side (front) in the moving direction of the frame 1 (block 1A). One end is connected to the other end, and a hoisting device for winding the pulling wire 12 to the other end and drawing the frame 1 (block 1A) is installed.

  The carriage 10 is inserted between the support plate 8 and the rail 11 with the base plate 31 b of the column member 31 (21) being lifted from the rail 5 by the jack 11. The cart 10 is attached to one column member 31 (21), or two or more carts 10 are installed on both sides of the column member 31 (21). When the column 3 is composed of a plurality of column members 31 and 32 arranged in parallel, the column members 32 other than the column members 31 supported by the rail 5 are in a suspended state as shown in FIG.

  After the frame body 1 (block 1A) including the column member 31 (21) is supported by the carriage 10, the frame body 1 (block 1A) is moved toward the installation position by winding the pulling wire 12 by the winding device.

  When the movement of the frame 1 (block 1A) is completed, the parallel column members 31 and 32 are lowered and fixed to the fixing unit as shown in FIG. As described above, during the movement of the block 1A, the column member 21 of the other column 2 and the column members 31 and 32 of the one column 3 opposed to the column member 21, as shown in FIG. The inner column members 31 and 21 are supported by the rails 5 and 5, and the column member 32 not supported by the rail 5 is in a state of floating δ from the level of the top end of the rail 5.

  From the state shown in FIG. 1- (a), as shown in FIG. 1 (c), the pillar 3 having a pair of pillar members 31 and 32 arranged in parallel may be lowered to the level of the fixing portion (fixing level). Direct transition from the state of (a) to the state of (c) is likely to apply an unreasonable force to the columns 2 and 3 and the beam 4 constituting the frame 1 (block 1A). In order to avoid such a situation, the entire structure 1 (block 1A) is lowered all at once from the state (a) to the state (assumed level) shown in (b). The simultaneous lowering of the entire frame 1 (block 1A) is performed by lowering all the jacks 11 supporting the frame 1 evenly.

  The “assumed level” shown in FIG. 1- (b) is the pillar of one pillar 3 composed of the parallel pillar members 31, 32 supported by the rail 5 as shown in FIG. 3- (a). When the bottom surface of the member 31 and the bottom surface of the column member 32 that has caused a displacement of δ above the level are lowered (jacked down) to the “fixing level” at the time of final fixing, the other column 2 This is the level assumed for the bottom surface of the other column member 21 when it is assumed that the bottom surface of the column member 21 and the bottom surface of the column member 31 are located on the same plane. This “assumed level” is positioned higher than the “fixing level” by Δ = L1 / L2 · δ.

  When the movement is finished and the bottom surfaces of the column members 21 and 31 are at the “rail level”, the descent of the frame 1 (block 1A) shown in FIG. After the state (b) at the “assumed level”, the bottom of the pillar members 31 and 32 is shifted to the state (c) at the “fixing level”.

  The bottom surfaces of the column members 21 and 31 placed on the rail 5 at the stage of FIG. 1- (a) and at the “rail level” are h (from “assumed level” to “rail” until the “assumed level” shown in FIG. It can be lowered (jacked down) by a height up to “level”. As the column member 31 is lowered, the column member 32 is also lowered. When the column members 21, 31, 32 are lowered, at least the rails 5 laid under the bottom surfaces of the column members 21, 31, 32 are disassembled and removed.

  From the “assumed level” to the “fixing level”, the bottom surface of the column member 31 placed on the rail 5 is lowered by Δ (L1 / L2 · δ) in the stage of FIG. -At the stage of (a) and (b), the bottom surface of the column member 32 that is in a state of being lifted by δ from the rail 5 is lowered by Δ + δ. The column member 31 is lowered (jacked down) while being supported by the jack 11 interposed thereunder, and the column member 32 is lowered as the column member 31 is lowered.

  After the bottom surfaces of the column members 31 and 32 are lowered to the “fixing level”, the bottom surfaces (base plates 31 b) of the column members 31 and 32 are fixed to the fixing portion (the foundation 14 and the like) and are fastened to the anchor 13. After the column members 31 and 32 are fixed to the fixing portion, the rails 5 remaining in the sections other than the bottom surface of the column members 21, 31, and 32 are disassembled and removed.

From the state of FIG. 1- (c), as shown in FIG. 1 (d), the other pillar 2 (column member 21) opposite to the lowered pillar 3 (column members 31, 32) is brought to the “fixing level”. It is lowered to fix the leg portion 21a of the column member 21 to the fixing portion, and to be fastened to the anchor 13. The descending amount of the column member 21 is Δ (L1 / L2 · δ).

1 ... Frame, 1A ... Block,
2 ... Column, 21 ... Column member, 21a ... Column base, 22 ... Column member,
3 ... Column, 31 ... Column member, 31a ... Column base, 31b ... Base plate, 32 ... Column member, 32a ... Column base, 33 ... Connecting member,
4 …… Beam,
5 ... rail, 6 ... bundle pillar, 61 ... spread mortar,
7 ... Bracket, 8 ... Support plate, 9 ... Guide member,
10 ... cart, 10a ... loading plate, 10b ... side plate, 10c ... horizontal plate, 10d ... chain, 10e ... roller,
11 ... Jack, 12 ... Towing wire, 13 ... Anchor,
14 ... Basic, 15 ... Leveling material.

Claims (2)

Slide the frame that has the pillars facing each other in the span direction and the beam spanned between both columns in the span direction as a basic element in the construction state so as to cross the span direction, and face each other at the installation position of the frame It is a method of fixing the leg portion of the column in a fixed state to each fixing portion located below the level at the time of sliding,
At least one of the opposing columns has a column member juxtaposed in the span direction, and the leg portion of any column member that receives a vertically upward force when the at least one column is fixed at the installation position. After sliding the frame to the installation position, with the opposing pillars placed on the track in a state of floating,
Lowering the parallel column member of the one column having the column member in the floated state, fixing the leg portion of the parallel column member to the fixing unit,
A method for installing a framed structure with columns, wherein the other column facing the one column is lowered to fix the leg portion to the fixing unit. The bottom surface of the column member that constitutes the other column when the column member that the one column is parallel to is landed on the fixing unit before the column member that the one column is aligned is lowered to the fixing unit. 2. The method for installing a framed structure according to claim 1, wherein the frame is lowered all at once to a level where the frame is located.

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