JP2003221875A - Railless slide method - Google Patents

Abstract

(57) [Summary] [Problem] In a sliding method of a truss roof or the like, a step of removing a temporary rail, jacking up and down is not required, cost reduction and construction period are shortened, and a relatively simple and low-cost slide is used. It is possible to easily prevent the lateral displacement of the roof unit with a simple device, and to perform the sliding operation quickly and safely at low cost. A sliding surface continuous in a sliding direction is formed on an upper surface of an upper beam 1a of RC or PCa of a lower frame 1 by a buried steel plate or the like. The unit 2U is brought into contact with the sliding surface, and is slid to the installation position while preventing lateral displacement by a lateral displacement prevention device provided on the lower surface thereof, and the unit 2U reaching the installation position is fixed to the upper beam 1a as it is with anchor bolts or the like. Traction jack 30 and a pump or the like is placed at the head of the unit 2U _1, the reaction force device 40 to be installed in the upper beam 1a utilizes the head of the column 1b fixed with diagonal member 42.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a slide construction method used for sliding (traveling) a large space steel frame roof of a structure during construction work.

[0002]

2. Description of the Related Art Slide methods for large-scale steel roofs, etc.
It is used when there are restrictions on site conditions and for the purpose of shortening the construction period. For example, one unit of an upper structure such as a steel frame roof is assembled on one side on a pre-constructed lower frame, and this upper part is assembled. The structure unit is slid by the width of one unit, the next unit is assembled in the empty space and added to the preceding unit, and the slide and assembly for one unit are alternately repeated to construct the upper structure.

(1) In such a slide construction method, generally, a temporary rail or H-shaped steel is installed on the upper surface of the upper beam of the lower frame and is slid on the track.

For example, in Japanese Unexamined Patent Publication No. 53-130813, a steel truss unit is provided with a roller and a center hole type jack for moving the truss, and the roller rolls on the upper surface of an upper beam of a lower reinforced concrete structure. Installing a temporary rail, installing a concrete column for reaction force that fixes the end part of the tow rod of the jack on the upper beam on the opposite side of the unit assembly, and pulling out the tow rod in the anti-travel direction by the jack, the steel truss The unit is sliding. After moving the steel truss, set the journal jacks on both ends of each steel truss to jack up, remove the temporary rail, then remove the roller, then jack down and bite the sole plate onto the upper beam. set.

Further, in Japanese Patent Laid-Open No. 8-28053,
A traveling rail made of steel with an H-shaped cross section is welded to the upper part of the steel column of the lower frame of the steel frame structure, and a sliding member such as OILES plate or Teflon (registered trademark) is provided between the traveling rail and the mega truss unit. Or, a slide jack having a jack function and a sliding function is interposed, one end is fixed to the mega truss unit, and the other end is connected to the traveling rail by a clamp device. ing. When using a slide jack, adjust the height of the mega truss unit (adjust the welding gap)
After that, the upper and lower steel frame columns are joined by welding.

(2) Usually, the jacks, pumps, and operators who slide the upper structure unit are often separated from each other in positional relationship, and there are many problems in safety or accuracy (quality). In order to make up for it, sensors were installed for centralized management.

[0007]

(1) When using the temporary rail as described above, when fixing the upper structure unit at a predetermined position (height), jack up the upper structure unit once. It is necessary to pull out the temporary rail, remove the roller, and then jack down. Due to the work, there were problems such as an increase in cost and extension of construction period.

Further, when the traveling rail of H-shaped steel frame and the special slide member or slide jack as described above are used, the cost of the device and the like increases. Further, it is necessary to prevent the upper structural unit from laterally shifting in the direction perpendicular to the slide when sliding.

(2) If the positional relationship among the jack, pump, and operator is far, it is necessary to attach a sensor or the like for centralized management, which causes a problem of increased cost.
Also, when the jack and pump are set on the side that will be the reaction force fulcrum, when sliding a long distance, it is necessary to move the jack and pump in accordance with the progress of the slide, which allows quick sliding work. There wasn't. If the pump is set at another location on the side of the unit that moves the jack, the length of the hydraulic hose becomes longer and the pressure loss increases. Furthermore, since the distance between the unit and the pump operator becomes long, visual confirmation and thorough signaling are insufficient, and there are many safety problems.

The present invention has been made to solve such a problem, and an object thereof is to eliminate the steps of removing a temporary material such as a rail and jacking up and down when a conventional temporary rail is used. The cost can be reduced and the construction period can be shortened. The upper structure unit can be slid with a relatively simple and low cost device, and the lateral displacement of the upper structure unit can be easily prevented with a simple device. It is possible to provide a railless slide method capable of performing a slide operation at low cost quickly and safely.

[0011]

According to claim 1 of the present invention, an upper structure (such as a steel truss roof) erected on a lower frame (such as a concrete structure) is divided into units, and the upper structure unit is divided. Slide from one side on the lower skeleton to the installation position, and repeat this sequence to build the upper structure.In the slide method, form a continuous sliding surface in the sliding direction on the upper surface of the upper beam of the lower skeleton. The lower surface of the slide plate provided on the lower surface of the structure unit is brought into contact with the slide surface to slide the upper structure unit to the installation position, and the upper structure unit reaching the installation position is fixed to the upper beam. This is a railless slide method.

According to the first aspect of the present invention, the temporary rail is eliminated and the steps of jacking up and jacking down are unnecessary. The sliding surface on the upper surface of the upper beam is RC
In the case of (reinforced concrete) construction or PCa (precast concrete) construction, a flat plate made of a steel plate is embedded in advance on the upper surface of the main RC beam or PCa beam, and the sliding surface is formed by this flat plate. When the lower frame has a steel frame structure, the upper surface of the steel beam can be used as the slide surface.

Further, it is preferable that the slide plate on the lower surface of the upper structure unit is made of a non-ferrous metal such as bronze or brass which is softer than a steel plate. Furthermore, a lubricant is applied to the lower surface and the sliding surface of this slide plate before sliding.
It is preferable to reduce friction. Further, a base plate is attached to the lower surfaces of both ends of the upper structure unit in the longitudinal direction (the direction perpendicular to the slide direction) so as to be located above the upper beam, and slide plates are attached to the lower surface of the base plate with bolts or the like.

When the upper structural unit reaches the predetermined installation position, the base plate is fixed to the upper beam as it is. When the lower skeleton has an RC structure or a PCa structure, an anchor hole is formed in advance, the base plate is fixed with an anchor bolt inserted in the anchor hole, and then the anchor hole is filled with a grout material to be fixed.

According to a second aspect of the present invention, in the railless slide construction method according to the first aspect, a lateral deviation prevention device is provided on the lower surface of the upper structure unit so as to be able to contact the side surface of the upper beam of the lower frame. The railless slide method is characterized by the following.

According to the second aspect of the present invention, since the upper structure unit slides on the slide surface having no rail, the upper structure unit is easily displaced in the direction perpendicular to the slide, and this lateral displacement is prevented. The lateral shift prevention device is provided with a mounting plate on the lower surface of the upper structural unit in proximity to the inner side surface of the upper beam, and mounts the circular arc guide plate guide on the mounting plate. Further, instead of the abutting plate, a lateral deviation correcting jack may be attached, and the lateral deviation may be corrected by pressing the head of the jack against the inner surface of the upper beam.

According to a third aspect of the present invention, in the railless slide construction method according to the first or second aspect, the traction drive device is installed in the upper structure unit, and the reaction force device is provided on the upper beam of the lower frame. The railless slide method is characterized in that the upper structure unit is slid by fixing the end portion of the tow cord to and pulling the tow cord with a towing drive device.

According to the third aspect of the present invention, a pulling drive device such as a jack, a drive source such as a pump, and an operator are centralized in one place and can be slid together with the upper structure unit. The tip of a tow line (cable, etc.) such as a center hole type jack is fixed to the reaction force device of the upper beam, and the tow line is extended in the anti-sliding direction with a jack or the like to slide the upper structure unit.

According to a fourth aspect of the present invention, in the railless slide construction method according to the third aspect, the reaction force device is installed on the upper surface of the upper beam of the lower frame, and the end portion of the tow line is fixed. The railless slide method is characterized by comprising a member and a diagonal member for fixing the fixing member to the head of the column of the lower skeleton.

According to the present invention, the reaction force device can be easily fixed to an arbitrary position of the upper beam, and the fixing member to which the end of the tow line (cable or the like) is fixed is the upper beam. Place it on the upper surface of the, and fix this fixing member to the head of the column of the lower skeleton using diagonally arranged diagonal members (steel rods for tension, etc.), and use the diagonal component to horizontally pull when sliding. Oppose force. The diagonal members are arranged in a pair of left and right so as to sandwich the upper beam from the direction perpendicular to the slide, and the fixing member and the pillar head of the lower skeleton are provided with a connecting member that extends horizontally in the direction perpendicular to the slide. Connect the ends of the diagonal. The stigma is
The slope of the corbel can be used.

According to the present invention having the above configuration, (1)
Slide the slide plate on the lower surface of the upper structure unit on the slide surface formed on the upper surface of the upper beam of the lower structure to slide the upper structure unit to the installation position, and leave the upper structure unit that has reached the installation position as it is. Since it is fixed to the upper beam, the steps of removing the temporary material such as the rail and jacking up and down when the conventional temporary rail is used are not required, and the cost and the construction period can be reduced.

(2) Since the slide surface made of a steel plate or the like and the slide plate made of bronze or brass are used, the upper structure unit can be slid by a relatively simple and low-cost device. Further, (3) by using a lateral deviation prevention device such as a guide plate provided on the lower surface of the upper structure unit, lateral deviation of the upper structure unit can be easily prevented with a simple device.

Further, (4) the traction drive device such as a jack, the drive source such as a pump, and the operator are integrated in one place, and
Since it can be slid together with the upper structure unit, it is not necessary to attach sensors etc. for centralized management,
When sliding a long distance, there is no need to move the jack and pump according to the progress of the slide, the length of the hydraulic hose does not increase and the pressure loss does not increase, and the distance between the unit and the pump operator is long. As a result, the visual confirmation and thorough signaling will not be insufficient and the safety will not be lowered, whereby the sliding operation can be carried out quickly and safely at low cost.

Further, (5) by using a reaction force device using a fixing member and a diagonal member, a reaction force can be applied to any of the columns of the lower skeleton, increasing the degree of freedom and facilitating installation, Replacement is also easy.

[0025]

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, the present invention will be described based on illustrated embodiments. This embodiment is an example applied to a case where a steel truss roof is installed on the lower frame of RC or PCa in a large space structure such as a factory.

FIG. 1 shows an outline of a large space structure to which the slide method and the same method of the present invention are applied, in which a lower frame 1 made of reinforced concrete (RC) or precast concrete (PCa) is left and right. Steel truss roof 2 is installed on top of this pair of lower structures 1,1
Is erected. The steel truss roof 2 is divided into a plurality of blocks in the longitudinal direction of the lower skeleton 1, and for example, one block of the steel truss unit 2U is assembled on one side in the longitudinal direction of the lower skeleton A on the manufacturing yard or the lower skeleton on the ground. When one block or a few blocks are assembled, the steel truss unit 2U that is slid to a predetermined installation position is fixed to the lower frame 1 by sliding it for a predetermined distance and repeating the assembly and the slide alternately.

According to the present invention, as shown in FIG. 1, the upper beam (RC beam or PCa) 1a of the lower frame 1 is directly provided with a steel truss unit 2U without provision of a temporary rail,
It is fixed to the upper beam 1a as it is in a predetermined installation position (see FIG. 2), and each steel frame truss unit 2U is provided with a lateral slip prevention (correction) device 20 (see FIG. 3), and the first steel frame truss unit 2U is provided. ₁ is provided with a tow jack 30 and the like (see FIG. 4), and a reaction device 4 is provided for receiving the reaction force of the tow jack
0 is used (see FIG. 6).

FIG. 2 shows an example of the railless structure of the present invention. Instead of a temporary rail, a flat plate 10 made of steel is previously embedded in the upper beam 1a of RC or PCa of the permanent structure. . An anchor 11 is attached to the flat plate 10 so as to be integrated with the concrete of the upper beam 1a, and is embedded so that the upper surface of the flat plate 10 is flush with the upper surface of the upper beam 1a.

A steel base plate 12 is attached by welding or the like to the lower surfaces of both ends of the steel frame truss unit 2U located above the upper beam 1a. The lower surface of the base plate 12 is a bronze slide plate. Alternatively, a slide plate 13 made of broth (brass) is attached with bolts or the like, and the lower surface of this plate 13 is flat plate 10
Abut on the upper surface of and slide it. Also, before sliding, the lubricant 14 is applied to the upper surfaces of the flat plate 10 and the slide plate 13, respectively, to reduce friction. The base plate 12 and the slide plate 13 are rectangular plates in a plan view, and are provided below the pair of lower chord members 2a in the sliding direction of the steel truss unit 2U.

When each steel truss unit 2U reaches a predetermined installation position, the base plate 12 is fixed to the upper beam 1a by anchor bolts 15 and nuts 16. Upper beam 1
An anchor hole is previously formed in the a by the corrugated pipe 17, and the anchor bolt 15 is inserted into this hole.
Then, the grout material 18 is filled and fixed. The anchor bolts 15 and the like are arranged at the four corners of the rectangular base plate 12, and one base plate 12 is fixed with a total of four anchor bolts 15.

FIG. 3 shows an example of a lateral slip prevention (correction) device 20 of the railless structure of the present invention, in which a mounting plate 21 is provided on each of the lower surfaces of a pair of lower chord members 2a of a steel truss unit 2U and an upper beam. 1a is mounted close to the inner side surface of the la, and a lateral deviation correcting jack 22 (FIG. 3 (a)) or a lateral deviation preventing guide member 23 (FIG.
(b)) Install.

The mounting plate 21 is composed of a substantially L-shaped steel plate 21a and a reinforcing plate 21b. A horizontal piece of the steel plate 21a is fixed to the lower surface of the lower chord member 2a by a bolt or the like, and the jack 22 or the base plate 24 of the guide member 23 is fixed. Is fixed to the vertical piece of the steel plate 21a with bolts or the like.

The jack 22 is, as shown in FIG.
With a head 22a that can be freely rotated by a spherical surface receiver,
By pressing the inner surface of the upper beam 1a with this head 22a, it is possible to correct the lateral displacement of the steel frame truss unit 2U in the direction perpendicular to the slide direction. The guide member 23 is shown in FIG.
As shown in FIG. 5, the contact plate 23a and the reinforcing plate 23b are R-processed so as to have a convex arc shape toward the upper beam 1a side in a plan view.
The contact plate 23a having a smooth arc abuts on the inner surface of the upper beam 1a, so that the sliding steel frame truss unit 2U can be smoothly guided and supported while preventing lateral displacement.

The jack 22 and the guide member 23 are
For example, the steel frame truss unit 2U is provided at each end portion in the longitudinal direction, and is slid while the lateral displacement is corrected by the jack 22, or the lateral displacement is corrected after reaching the installation position.

FIG. 4 shows the overall arrangement of the towing jack 30 and the reaction force device 40 of the present invention, and FIG. 5 shows a partial side view thereof. As shown in FIG. 4, the tow jacks 30 are installed directly above the upper beams 1a at both ends of the leading steel truss unit 2U _{1 in} the longitudinal direction (sliding right angle direction), and on the floor of the steel truss unit 2U ₁ , Operator 3 with pump 31 installed
Place 2.

A reaction force device 40 (described later) is fixed to the upper surface of the upper beam 1a at a position distant from the traveling direction, the end of the pulling cable 33 of the pulling jack 30 is fixed to the reaction force device 40, and the pulling jack 30 is used. The steel truss unit 2U ₁ is slid in the girder direction of the lower frame ₁ by paying out the traction cable 33 in the anti-travel direction. Further, a monitor 34 is arranged along the upper beam 1a, and a tape 35 with a scale is attached to the side surface of the upper beam 1a to monitor the sliding condition.

Towing jack 30, pump 31, operator 3
2 are integrated in one place and move with the slide of the steel truss unit 2U as it is, so you can confirm by pointing and calling with a small number of people without using a large sensor or centralized management system be able to. In addition, when the slide distance is long, it is not necessary to replace the jack and the pump.

The tow jack 30 is a center hole jack for pulling and moving the cable by alternately repeating the grasping of the penetrating cable and the expansion and contraction of the piston, and as shown in FIG. 5, the base portion thereof has a steel truss unit 2U _1.
The tow cable 33 is fixed to the lower chord member 2a and is fed backward by the cable guide 36.

FIG. 6 shows an example of the reaction force device 40 of the present invention. This reaction force device 40 is installed on the upper surface of the upper beam 1a and the end portion of the traction cable 33 is fixed. It is composed of a fixing member 41 and a pair of left and right diagonal members 42, 42 sandwiching the upper beam 1a for fixing the fixing member 41 to the head of the concrete column 1b of the lower frame 1.

The fixing member 41 is formed by combining two H-shaped steels in parallel and reinforcing them with reinforcing ribs. The traction cable 33 is inserted into the formed hollow portion and the fixing plate is provided at the end portion on the side opposite to the jack. The pulling cable 33 through the fixing member 44 and the fixing member 44.
Fix the tip of the. Such a fixing member 41 is placed on the upper beam 1a via the base member 45 made of H-shaped steel.

The diagonal member 42 is a steel rod for tensioning or the like, and is obliquely arranged in a side view, the upper end is attached to the connecting member 46 above the fixing member 41, and the lower end is the head of the concrete column 1b. Attached to the connecting member 47. The connecting members 46 and 47 are made of a pair of groove-shaped steel members that extend horizontally in the direction perpendicular to the slide, and a mounting table 48 having a triangular shape in a side view is integrally provided on the fixing member 41. The center portion of the connecting member 46 is placed on the connecting member 46, and the upper ends of the diagonal members 42 are inserted into both ends of the connecting member 46, respectively, and fixed by the nut 49 and the washer 50. The head of the concrete pillar 1b uses the inclined surface of the corbel 1c,
A receiving plate 51 is interposed between the inclined surface and the connecting member 47, the lower ends of the oblique members 42 are inserted into both ends of the connecting member 47, and fixed with nuts 49 and washers 50.

In such a reaction force device 40, the horizontal tensile force of the tow jack 30 is opposed by the horizontal component force of the diagonal member 42. Since it is a type that is hooked on the corbel 1c of the pillar, it is possible to apply a reaction force to any pillar, has a high degree of freedom, is easy to install, and is easy to rearrange.

As shown in FIG. 7, since the reaction force device 40 cannot be used in the final step of the erection work, the pulling cable 3 is directly connected to the pillar 1b 'of the lower body 1 at the end portion.
The tip of 3 may be fixed.

Needless to say, the present invention can be applied not only to the illustrated example but also to a slide construction method for other structures.

[0045]

[Effects of the Invention] (1) Slide the upper structure unit to the installation position by sliding the slide plate on the lower surface of the upper structure unit on the slide surface formed on the upper surface of the upper beam of the lower frame, Since the arrived upper structure unit is fixed to the upper beam as it is, it is not necessary to remove the temporary materials such as rails and jack up and down steps when using the conventional temporary rail, and the structure slide method In, it is possible to reduce the cost and shorten the construction period.

(2) Since the slide surface made of a steel plate or the like and the slide plate made of bronze or brass are used, the upper structure unit can be slid by a relatively simple and low-cost device, and the cost can be further reduced. it can.

(3) By using a lateral deviation prevention device such as a guide plate provided on the lower surface of the upper structure unit, lateral deviation of the upper structure unit can be easily prevented with a simple device, and the cost can be reduced. Also, the construction period can be shortened.

(4) A pulling drive device such as a jack, a drive source such as a pump, and an operator are centralized in one place and can be slid together with the upper structure unit, so that a sensor or the like needs to be attached for centralized management. There is no need to move the jack and pump as the slide progresses when sliding over long distances, the length of the hydraulic hose does not increase and pressure loss does not increase, and the unit and pump operator's There is no decrease in safety as the distance becomes longer and visual confirmation and thorough signaling are insufficient.
As described above, the sliding operation can be performed quickly and safely at low cost.

(5) By using a reaction force device using a fixing member and a diagonal member, it is possible to apply a reaction force to any of the columns of the lower skeleton, which increases the degree of freedom, facilitates installation, and allows relocation. It will be easy.

[Brief description of drawings]

FIG. 1 shows an outline of a large space structure to which the slide method and the same method of the present invention are applied, (a) is a front view,
(b) is a side view.

FIG. 2 is a cross-sectional view showing an example of a railless structure used in the slide method of the present invention.

FIG. 3 shows an example of a lateral deviation prevention (correction) device used in the slide construction method of the present invention, (a) is a side view of the apparatus using a lateral deviation correction jack, and (b) is a lateral deviation prevention device. It is a perspective view of the apparatus by the guide plate.

FIG. 4 is a side view showing an overall arrangement of a towing jack, a reaction force device and the like in the slide construction method of the present invention.

5 is a partial detailed view of FIG. 4, (a) is a side view of a jack part, and (b) is a side view of a steel truss unit part.

FIG. 6 is a reaction force device used in the slide method of the present invention, (a) is an overall side view, and (b) is a cross-sectional view of an upper part.

FIG. 7 is a side view showing a reaction force device provided on the end portion of the structure.

[Explanation of symbols]

1 ... Lower body (RC or PCa, etc.) 1a ... upper beam 1b ... Pillar 1c ... Corbel 2 ... Steel truss roof (upper structure) 2U ... Steel truss unit (upper structure unit) 2a ... Lower chord material 10-flat plate 11 …… Anchor 12 ... Base plate 13 ... Slide plate 14 ... Lubricant 15 ... Anchor bolt 16 ... Nut 17 ... Corrugated pipe 18 ... Grout material 20 ... Side slip prevention (correction) device 21 ... Mounting plate 22 ... Jack for lateral deviation correction 23 ... Guide member for preventing lateral displacement 24 ... Board 30 ... Tow jack 31 ... Pump 32: operator 33 ... Towing cable 34 ... Observer 35 ... Tape with scale 36 ... Cable guide 40 ... Reaction force device 41: fixing member 42 ... diagonal material 43: Fixed plate 44: fixing member 45: Basic member 46 ... Connecting material 47 ... Connecting material 48: Mounting table 49 …… Nut 50 ... washers 51 ... Receiving plate

   ─────────────────────────────────────────────────── ─── Continued front page    (72) Inventor Hirohira Takahashi             Kashima-ken, 1-2-7 Moto-Akasaka, Minato-ku, Tokyo             Inside the corporation (72) Inventor Kazuhiko Nishikawahara             Kashima-ken, 1-2-7 Moto-Akasaka, Minato-ku, Tokyo             Inside the corporation F-term (reference) 2E174 AA01 BA05 CA07 CA43 DA03

Claims (4)

[Claims] 1. An upper structure constructed by dividing an upper structure erected on a lower skeleton into units, sliding the upper structure unit from one side on the lower skeleton to an installation position, and repeating this sequence in sequence. In the slide construction method, a continuous sliding surface is formed on the upper surface of the upper beam of the lower frame, and the lower surface of the slide plate provided on the lower surface of the upper structure unit is brought into contact with the sliding surface to form the upper structure. A railless slide method characterized by sliding the body unit to the installation position and fixing the upper structure unit that has reached the installation position to the upper beam. 2. The railless slide method according to claim 1, wherein a lateral slip prevention device is provided on the lower surface of the upper structure unit so as to be able to contact the side surface of the upper beam of the lower frame. Railless slide construction method. 3. The railless slide construction method according to claim 1 or 2, wherein a traction drive device is installed in the upper structure unit, and a reaction force device provided on the upper beam of the lower frame is attached to the end of the traction rope. A railless slide method in which the upper structure unit is slid by fixing the part and pulling the tow cord with a towing drive device. 4. The railless slide construction method according to claim 3, wherein the reaction force device is installed on the upper surface of the upper beam of the lower skeleton, and the end portion of the tow cord is fixed, and the fixing member. Railless slide method, which is equipped with a diagonal member that fixes the column to the head of the column of the lower frame.