JP3476129B2 - Bridge reinforcement method - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a bridge reinforcing method for introducing prestress to a girder constituting a bridge by using a post tension method.

[0002]

2. Description of the Related Art Due to the recent increase in traffic volume and passing vehicle weight, stricter safety and durability standards are required for bridges than before, and it is necessary to reinforce old bridges that do not meet the new safety and durability standards. There is. For this reason, the post-tension method is widely used as a means of introducing prestress to existing bridges and reinforcing them. For example, as shown in FIG. 11, when a dead load or a live load is applied to a bridge girder 70 having an H-shaped cross section, the bridge girder 70 is deformed into a bow, and a compressive stress 71 acts on the upper flange 70a thereof, and the lower flange 70c. Since tensile stress 72 acts on the bridge girder 70
The load bearing capacity of the compressive stress 71 or the tensile stress 72 is
Depends on the load when the allowable stress limit is reached.
The post-tension reinforcement construction method is a construction method in which a compressive stress (compressive pre-stress, pre-stress) in the girder direction is introduced into the lower flange 70c in order to increase the load bearing capacity, and the tensile stress is relaxed.

As a conventional post tension method, as shown in FIG. 12, a lower flange 80c of a bridge girder 80 is used.
The external post-tension construction method in which an outer cable 85 that is in a tensioned state with tightening tools 83 and 84 is stretched between saddles 81 and 82 fixed to each other to introduce prestress to the lower flange 80c is the mainstream. The effectiveness of this construction method has been reported, for example, in "Stress analysis in the vicinity of the cable anchorage portion in reinforcing the outer cable of the main girder" (September 1997, 52nd Annual Scientific Lecture Meeting of Japan Society of Civil Engineers).

[0004]

However, the above-mentioned external post-tension construction method using the outer cable has the following problems (1) and (2). (1)
Although the above outer cable is made of PC steel or the like, such an outer cable cannot increase the rigidity of the bridge girder, so that the fatigue strength of the bridge girder cannot be improved. (2) Also, piping or the like is attached to the bridge. However, in the construction method using the above-mentioned outer cable, the mounting space is sacrificed in order to attach the outer cable or saddle.

In view of these problems, the present invention intends to solve the problems by introducing prestress to the bridge girder by a method different from the conventional post-tensioning method, increasing the rigidity of the bridge girder to improve fatigue strength, and further It is to provide a method of reinforcing a bridge that can easily secure a suspension space.

[0006]

In order to achieve the above object, a method of reinforcing a bridge according to the present invention is to dispose a post tension reinforcing plate on the lower surface of a girder to be reinforced of the bridge, One end is fixed to the reinforcing girder, and the tension reinforcing plate is arranged in series in the girder row direction at a proper position on the lower surface of the reinforcing girder so as to be close to the other end of the post tension reinforcing plate. The other end and one end of the tensile reinforcing plate are connected to the reinforcing girder at the same time by using bolts and nuts via the splicing plate, and then attached to the reinforcing girder, after which a tensile load is applied to the other end of the tensile reinforcing plate, The tensile load is transmitted to the post tension reinforcing plate by the shearing force acting between the tension reinforcing plate and the post tension reinforcing plate and the splicing plate through the bolt, and after reaching a predetermined tensile load. , By fixing the other end of the serial post-tensioning reinforcement plate to be reinforced digits, by introducing a post tension to the reinforcement girder, it is characterized in that to reinforce the be-reinforced spar.

Here, after the post tension is introduced into the reinforcing girder, the tension reinforcing plate is used as a new post tension reinforcing plate and the above procedure is repeatedly applied, and a plurality of post tension reinforcing plates are used to reinforce the reinforcing girder. It is also preferable to continuously reinforce.

In the step of transmitting the tensile load to the post tension reinforcing plate, (1) a bolt used to connect the other end of the post tension reinforcing plate and one end of the tensile reinforcing plate, An impact load is applied to the nut or the attachment plate, and (2) at this time, the tightening torque of the bolt used to connect the other end of the post tension reinforcing plate and one end of the tensile reinforcing plate is It is desirable to loosen it. As a result, the frictional resistance acting on the contact surface between the tension reinforcing plate and the post tension reinforcing plate and the reinforcing girder and the splicing plate is released, and the tensile load is smoothly increased to the desired level for the post tension reinforcing plate. It is possible to apply a tensile load of.

A jack, preferably a center hole jack, can be used as a specific means for applying a tensile load to the other end of the tensile reinforcing plate. In this case, it is desirable to connect the tension rod of the jack and the other end of the tension reinforcing plate via a joint plate.

Further, in the step of transmitting a tensile load to the post tension reinforcing plate, the bolt connecting the other end of the post tension reinforcing plate and the one end of the tensile reinforcing plate is compared with the bolt hole of the reinforced girder. Then, using a small-diameter bolt, transmit the tensile load to the post tension reinforcing plate in this state, then replace the small-diameter bolt with a drift pin, and then replace the drift pin with a larger-diameter bolt than the small-diameter bolt. It is desirable to replace it with the above and transfer the tensile load to the post tension reinforcing plate in this state.
Thereby, when the small diameter bolt is used, it is possible to smoothly apply a tensile load to the post tension reinforcing plate without the shaft portion of the small diameter bolt hitting the bolt hole wall surface of the girder to be reinforced. When replacing a small diameter bolt with a drift pin, the deviation between the bolt hole of the girder to be reinforced and the bolt hole of the reinforcing plate is corrected, and then the drift pin is replaced with a large diameter bolt, so the large diameter bolt shaft portion Is reliably prevented from hitting the bolt hole wall surface of the reinforced girder.

Further, the reinforcement range of the reinforcement girder between the long spans also becomes longer, but in such a case, if only both ends of the post tension reinforcing plate to which a tensile load is applied are fixed to the reinforcement girder, the middle of the reinforcement plate is reached. The shearing force may not be smoothly transmitted between the reinforcing plate and the girder to be reinforced, and the reinforcing effect may be relatively reduced. Further, when a camber (warpage due to a compressive load) occurs in the reinforced girder, a gap is generated between the reinforced girder and the reinforcing plate, which is likely to be disadvantageous in terms of anticorrosion. Therefore, after transmitting a predetermined tensile load to the post tension reinforcing plate, the post tension reinforcing plate is welded and fixed to the reinforced girder over the entire length in the girder row direction or partially by arc welding or the like. It is desirable to fix with force bolts.
Alternatively, after transmitting a predetermined tensile load to the post tension reinforcing plate, the post tension reinforcing plate is adhered to the reinforced beam, and then the other end of the post tension reinforcing plate is fixed to the reinforced beam. It is also desirable to introduce post tension into the reinforced girder.

The lower surface of the reinforcing girder may be divided into a plurality of reinforcing regions in the direction perpendicular to the girder rows, and post tension may be introduced into the reinforcing girder for each reinforcing region. As a result, as compared to the case where one post tension reinforcing plate is used to reinforce the entire region of the girder to be reinforced, the post tension per plate can be reinforced by using a plurality of post tension reinforcing plates. The tensile load (hereinafter referred to as the post tension load) required for application is small, and the weight of each post tension reinforcing plate is small, which facilitates construction. Particularly when reinforcing a wide girder to be reinforced, it is possible to reduce the eccentric load by adjusting the post tension load in each reinforcing region.

[0013]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Various embodiments of a bridge reinforcing method according to the present invention will be described below with reference to the drawings. 1 is a schematic view showing an embodiment of a bridge reinforcing method according to the present invention, and FIG. 2 is a bottom view of FIG. In this embodiment, a bridge girder (main girder) having an H-shaped cross-sectional shape including an upper flange 1a, a web 1b and a lower flange 1c.
1 is the reinforced girder. The present invention, as the reinforced girder,
The present invention is not limited to the bridge girders having the H-shaped cross section of the present embodiment, and can be applied to box girders, floor girders, longitudinal girders, floor slabs, steel girders, concrete girders, composite girders of steel and concrete, and the like.

First, the post tension reinforcing plate 3 is arranged along the girder row direction on the lower surface of the lower flange 1c of the bridge girder (main girder) 1 to be reinforced, and the right end of the post tension reinforcing plate 3 is arranged. Connect the portion 3a to the high-strength bolts 4A, 4A, ...
And nuts 4B, 4B, ... Are used to fasten the lower flange 1c. Incidentally, instead of bolting one end 3a of the post tension reinforcing plate 3 to the lower flange 1c, an adhesive such as an epoxy resin may be used for adhesion or welding for fixation. Next, a tension reinforcing plate 4 is arranged in series on the lower surface of the lower flange 1c and adjacent to the post tension reinforcing plate 3, and one end 4a of this tension reinforcing plate 4 and the other post tension reinforcing plate 3 are arranged. Edge 3
and b are arranged close to each other. Then, one end 4a of the tension reinforcing plate 4 and the other end 3b of the post tension reinforcing plate 3
At the same time that the splicing plate 5 is spliced to the lower surface of and the two splicing plates 6 sandwiching the web 1b on the upper surface of the lower flange 1c
A, 6B (a splicing plate indicated by reference numeral 6B is not shown) are spliced, and high-strength bolts 7A, 7A, ... And nuts 7B, 7B ,.
Using, the splicing plate 5, the other end 3b of the post tension reinforcing plate 3 and the one end 4a of the tensile reinforcing plate 4 are bolted to the lower flange 1c. Here, the high-strength bolt 7A,
7A, ... Are tightened without being fully tightened. In addition,
The section reinforced by the tension reinforcing plate 4 is called section 1, and the section reinforced by the post tension reinforcing plate 3 is called section 2.

The other end 4b of the tensile reinforcing plate 4 in the section 1
Are bolts 8, 8, 8 fixed to the joint plate 9 by welding.
8 is used to connect to the joint plate 9. Instead of this, a convex portion or a concave portion is provided on the joint plate 9 or the other end portion 4b of the tensile reinforcing plate, and the joint plate 9 and the other end portion 4b of the tensile reinforcing plate are engaged with each other by concavo-convex engagement to fix them to each other. May be.

Tension rods 10a and 11a inserted into hydraulic center hole jacks 10 and 11 are welded and fixed to both ends of the joint plate 9 in the direction perpendicular to the girders. Further, the jack fixing jig 12 is bolted to the lower flange 1c by using high-strength bolts 13A, 13A, and the end faces of the center hole jacks 10, 11 are fixed portions 12a, 12 of these jack fixing jigs 12.
When the tension rods 10a and 11a are brought into contact with b, and the jack thrust is exerted in this state to pull the tension rods 10a and 11a, the end faces of the center hole jacks 10 and 11 are fixed to the fixing portion 12a and
It is fixed by pressure to 12b. Here, the mounting positions of the bolts 8, 8, ... For joining the joint plate 9 and the tensile reinforcing plate 4 are
From the viewpoint of improving the transmission of the tensile load, the mounting position of the high-strength bolts 7A, 7A, ... Used for joining the one end 4a of the tensile reinforcing plate 4 to the lower flange 1c and the bridge axis direction (column direction) It is preferable to make them substantially equal.

With the above structure, first, the center hole jacks 10 and 11 are operated to move the tension rod 10
By pulling a and 11a leftward in the bridge axis direction and transmitting the tensile load to the joint plate 9, the tensile load is applied to the tensile reinforcing plate 4. At the same time, by pulling the tension rods 10a, 11a, the center hole jacks 10, 11
The reaction force acting on the lower flange 1c is transmitted to the lower flange 1c via the jack fixing jig 12, and an eccentric compression load is applied to the bridge girder 1 to give a compressive stress to the lower flange 1c.
Further, the tensile load acting on the tensile reinforcing plate 4 is transmitted to the attaching plate 5 through the shearing force via the bolt between the one end portion 4a of the tensile reinforcing plate 4 and the adding plate 5, and then the adding plate 5 is attached. Board 5
It is transmitted to the post tension reinforcing plate 3 through a shearing force via a bolt between the post tension reinforcing plate 3 and the post tension reinforcing plate 3.

In this way, the center hole jack 1
The thrust of 0 and 11 is gradually increased and the jack load is gradually increased to increase the tensile load applied to the post tension reinforcing plate 3 in the section 2. However, when the jack load reaches a certain value, it is difficult to further increase. Become. That is, as the jack load increases, the contact surface between the lower flange 1c and the post tension reinforcing plate 3 and the tensile reinforcing plate 4, as well as the splicing plate 5, the post tension reinforcing plate 3 and the tensile reinforcing plate 4.
The point frictional resistance and the surface frictional resistance on the contact surface with and become stronger, these frictional resistances outweigh the jack load, and the tensile load of the post tension reinforcing plate 3 does not become higher than that. FIGS. 3A and 3B schematically show an example of this state. In FIG. 3, reference numeral 1c is a lower flange, 7A is a splicing bolt, 7B is a nut, 5 is a splicing plate, and 3 is a post tension reinforcing plate. Figure 3
As shown in (a), since the above-mentioned frictional resistance acts strongly, the post tension reinforcing plate 3 slightly bends and deforms. In particular, the point frictional resistance acts particularly high at points A1, A2 and B and may exceed the surface frictional resistance.

Therefore, in order to release the frictional resistance and the surface frictional resistance at these points of action, the tightening torque of the splicing bolt 7A is reduced as the first operation, and the second operation is as follows.
As shown by arrows 14 and 15 in FIG.
An impact load is applied to the ends of B and 7B to the left in the bridge axial direction. By inserting these operations, the frictional resistance force is released, the post tension reinforcing plate 3 moves a minute distance and bending deformation disappears, and the state shown in FIG. At the same time, since the post tension reinforcing plate 3 moves a minute distance, the jack load is slightly reduced, and then the lowered jack load is again increased to a predetermined post tension load. By repeating this procedure,
The jack load does not lose against the frictional resistance force, and
The tensile load transmitted to the post tension reinforcing plate 3 and acting on the post tension reinforcing plate 3 can be further increased. The impact load may be applied once or a plurality of times by using a hammer or the like by human force or mechanical force. In addition, the above procedure is the same as the tensile reinforcement plate 4 in the section 1.
It is preferable to perform the same in the one end portion 4a. In this case, as shown in FIG. 1, an impact load may be applied to the ends of the nuts 7B and 7B in the directions of arrows 16 and 17.
The direction of the impact load is effective in the direction of the arrow, but is not limited to this direction. This is because the vibration generated by the impact load applied in any direction can also release the frictional resistance force of the contact surface.

In this way, the procedure for increasing the jack load is executed while inserting the operation for loosening the bolt tightening torque and the operation for applying the impact load, and this procedure is repeated until the jack load does not change. After the jack load does not change, the nuts 7B, 7B, ... Are further tightened to fasten the end 3b of the post tension reinforcing plate 3 to the lower flange 1c, and the introduction of post tension to the bridge girder 1 in the section 2 is completed. To do.

The longer the span of the girder to be reinforced is, the longer the reinforced range is. However, if only the both ends of the reinforced plate are fixed and the post tension is reinforced as described above, the shearing force is smooth in the middle of the reinforced plate. However, the response stress to live load depends on the average displacement between the fixed points of the reinforcing plate, and the reinforcing effect of the post tension reinforcing plate at the position where the bending moment is maximized is larger than that at both ends. Will be reduced. In addition, since the bridge girder usually has a camber, a gap is created between the post tension reinforcing plate and the lower flange,
It may be disadvantageous in terms of anticorrosion.

Therefore, it may be advantageous to fix the reinforcing girder and the post tension reinforcing plate. Specifically, after transmitting a predetermined tensile load to the post tension reinforcing plate, the post tension reinforcing plate is welded and fixed to the reinforced girder over the entire length in the girder row direction by arc welding, or It is desirable to fix with high strength bolt joints. As a form of arc welding, it is preferable that fillet welding is performed in the bridge girder row direction with the plate width of the post tension reinforcing plate being different from the width of the girder to be reinforced. It is important that the fillet welding is continuous welding or intermittent welding, and that the strength necessary for transmitting the shearing force is secured. On the other hand, when fixing using high-strength bolts, the post-tension reinforcing plate is fixed to the reinforced girders with high-strength bolts arranged at intervals within a pitch that can secure the strength required to transmit shearing force. Is desirable.

In addition to the fixing method in which the reinforced girder and the post tension reinforcing plate are welded or the high-strength bolts are joined as described above, a fixing method by adhesion is also preferable. That is,
After applying a predetermined tensile load to the post tension reinforcing plate 21, as shown in FIG.
The lower flange 1c and the lower flange 1c are adhered to each other with an adhesive 22, and thereafter, the post tension reinforcing plate 21 and the lower flange 1c are sandwiched by a spring clip 23 to be pressure-bonded to each other. Here, as the adhesive, an epoxy adhesive is particularly effective for transmitting the shearing force, and a plurality of spring clips are used to continuously or intermittently post-reinforce the reinforcing plate 21 and the lower flange 1c. You can fix and. If the adhesive has a large adhesive strength after curing, a vise or the like can be used for temporary fixing instead of the spring clip.

Incidentally, the bolt holes of the lower flange 1c have a diameter larger than the outer diameter of the shaft portion of the splicing bolt 7A so as not to come into contact with the shaft portion of the splicing bolt 7A when transmitting a tensile load to the post tension reinforcing plate 3. Processed to have a large diameter,
Further, the bolt holes of the post tension reinforcing plate 3, the tensile reinforcing plate 4, and the splicing plates 5, 6A, 6B have substantially the same size as the outer diameter of the splicing bolt shaft portion so that the shearing force can be smoothly transmitted. It is preferably processed to have a diameter of. Regarding the bolt hole diameter of the lower flange 1c, it is stipulated in the specifications that the hole diameter is larger than the outer diameter of the splicing bolt shaft portion.
It is fully feasible to machine the bolt hole so that it does not come into contact with the splicing bolt shaft.

Even so, in the process of transmitting the tensile load to the post-tension reinforcing plate 3, the amount of movement of the above-mentioned tensile-reinforcing plate 4 and the post-tension-reinforcing plate 3 is large, and the splicing bolt shaft part is in the bolt hole of the lower flange 1c. When there is a risk of contact, there is a means for processing the bolt hole into an oval shape in the bridge axis direction, but this means is costly and time consuming and is economically disadvantageous.

Therefore, in such a case, a construction method using a drift pin (a rod having a tapered tip portion) is preferable. This construction method is as follows. First, as shown in FIG. 1, as the splicing bolts 7A, 7A, ... Used for attaching the post tension reinforcing plate 3 and the tensile reinforcing plate 4 to the lower flange 1c, the nominal screw size is M20.
Use a small diameter bolt such as. Then, the center hole jacks 10 and 11 are operated to apply a tensile load to the tensile reinforcing plate 4, and the tensile load is ⅓ to ⅕ of the planned amount.
By introducing such a degree, the amount of deviation between the bolt holes of the post-tension reinforcing plate 3 and the tensile reinforcing plate 4 and the bolt holes of the lower flange 1c is kept low. Next, the splicing bolt 7
A, 7A, ... are sequentially replaced with a large diameter drift pin with a diameter of 22φ, etc. At this time, since the diameter of the drift pin is large, the lower flange 1c is symmetrical with respect to the bridge axis so that an eccentric load is not generated. It is preferable to replace the bolts in position at the same time. In this way, the amount of displacement of the relative positions of the bolt holes of the post tension reinforcing plate 3, the tensile reinforcing plate 4, and the splicing plates 5, 6A, 6B with respect to the bolt holes of the lower flange 1c is corrected. In addition, all the attachment bolts 7A, 7
After A, ... Are replaced with the drift pins, it is confirmed that these drift pins do not contact the wall surface of the bolt hole of the lower flange 1c. Next, the drift pin is replaced with a splicing bolt having the same diameter, and in this case also, it is preferable to replace the drift pin at a symmetrical position with respect to the bridge axis at the same time so that an eccentric load is not generated in the lower flange 1c. Then, after replacing all the drift pins, the tensile load applied to the tensile reinforcing plate 4 is increased to a predetermined amount of post tension load, and the work is completed.

By the way, in the above embodiment, in order to easily transmit the jack load to the post tension reinforcing plate 3, the tension rods 10a and 11a of the hydraulic center hole jacks 10 and 11 and the tension reinforcing plate 4 form the joint plate 9. However, the present invention is not limited to this, and a tensile load may be applied to the tensile reinforcing plate 4 using a wire made of, for example, PC steel material. The jack load is appropriately set so that the load response of the entire structure including the bridge girder can be structurally calculated and the safety of the bridge girder can be maintained against a live load.

Further, following the reinforcing step of the above-mentioned embodiment, a plurality of post tension reinforcing plates are arranged in series in the girder row direction on the lower surface of the reinforced girder so that the reinforced girder can be continuously reinforced. It is possible. That is, the post-tension reinforcing plate 3 to which a predetermined tensile load is applied as described above.
After fastening the lower flange 1c, the jack fixing jig 1
2 is removed from the lower flange 1c, the joint plate 9 is removed from the tensile reinforcing plate 4, and then the tensile reinforcing plate 4 is
Post tension reinforcement plate.

Next, a second tension reinforcing plate adjacent to the second post tension reinforcing plate 4 is arranged in series, and the second flange using the bolt hole of the lower flange 1c used for attaching the joint plate The end portions of the post tension reinforcing plate and the second tensile reinforcing plate are connected to each other via the splicing plate in the same manner as above. Then, using a center hole jack, a jack load is applied to the other end of the second tension reinforcing plate to apply a predetermined post tension load to the second post tension reinforcing plate, and then the second post tension reinforcing plate is fastened to the girder to be reinforced. By repeating such a reinforcing procedure, it becomes possible to continuously provide a plurality of post tension reinforcing plates in the girder row direction and continuously reinforce the girder to be reinforced (main girder).

An example in which the main girder is continuously reinforced in this way is shown in FIG. According to the figure, the main girder 1 is provided with a plurality of post tension reinforcing plates 30 and 3 to which a predetermined tensile load is applied.
1, 32 are attachment plates 33, 34A, 34B, 35, 36
They are connected to each other by A and 36B, and at the same time, they are bolted to the lower flange 1c. Incidentally, the attachment plate 34
B and 36B are lower flanges 1 on the back side with the web 1b interposed therebetween.
Since it is arranged on c, it is not shown. Also, reference numeral 37A,
38A and 39A are bolts, and 37B, 38B and 39B are nuts. The post tension reinforcing plate 32 at the end is also a tensile reinforcing plate for transmitting a tensile load to the adjacent post tension reinforcing plate 31, and its end 32
A bolt for connecting the joint plate to the end portion 32a was inserted into the bolt holes 46, 46, ... Of a. Also,
After applying a predetermined tensile load to the post tension reinforcing plate 32, the bolt holes 4 of the post tension reinforcing plate 32
0, 40, ... and bolt holes 41, 4 of the lower flange 1c
The bolts 39A, 39A, ... Are inserted into 1, and the post tension reinforcing plate end portion 32a is fastened and fixed to the lower flange 1c using nuts 39B, 39B ,.
It should be noted that high strength bolts may be inserted into the bolt holes 46, 46, ..., 47, 47, ... Remaining after the joint plate and the jack fixing jig are removed and fastened to take measures to prevent the strength reduction of the bridge girder. .

By the way, when the reinforcing girder is continuously reinforced in this manner, the bolt holes 46 used for connecting the joint plate to the end portion 32a of the post tension reinforcing plate 32 located at the terminal end. 46, ... will eventually remain. The bolt holes 40, 40 used to fasten the post tension reinforcing plate 32 to the lower flange 1c are formed slightly closer to the center than the bolt holes 46 used to fasten the joint plate. Therefore, the reinforcing effect at the reinforcing plate end portion 32a is lower than that of the other post tension reinforcing plates 30 and 32. Therefore, such a reinforcing plate end portion 32a
The construction method for preventing the deterioration of the reinforcing effect in the above will be described below.

FIG. 6 is a bottom view similar to FIG.
2 is different from the configuration shown in FIG. 2 in that the joint plate 9 is arranged slightly closer to the center than the position shown in FIG.
The long tension rod 1 is connected to the end portion 4b by using a bolt hole provided slightly near the center of the end portion 4b of the tension reinforcing plate.
The point is that 0a 'and 11a' are prepared and fixed to the joint plate 9. It should be noted that, in FIG. 6, members given the same reference numerals as those in FIG. 2 have the same configuration, and detailed description thereof will be omitted. With such a structure, the bolt hole 4 is provided between the joint plate 9 and the jack fixing jig 12 at the end portion 4b of the tensile reinforcing plate.
2, 42, 42, 42 remain, and these bolt holes can be used as bolt holes for fastening the tensile reinforcing plate end portion 4b to the lower flange 1c. Finally the tensile reinforcement plate end 4
FIG. 7 shows a state in which b is fastened to the lower flange 1c.
Is. However, since the tensile load does not act on the tensile reinforcing plate end portion 4b between the joint plate 9 and the jack fixing jig 12,
After applying a predetermined amount of post-tension load to the tensile reinforcing plate 4, the tensile reinforcing plate end portion 4b is bolted to the lower flange 1c using the bolt holes 42, 42, 42, 42, and the joint plate 9 is attached to the tensile reinforcing plate. When unloading from No. 4 and unloading, the pre-stress given to the relevant reinforcement area of the lower flange 1c will be slightly lower than the planned amount. Therefore, the tensile load applied to the tensile reinforcing plate 4 needs to be set higher than the planned amount. The number of high-strength bolts used to fasten the end portion 4b of the tension reinforcing plate is set to the minimum number capable of supporting the post tension load applied to the tension reinforcing plate 4, and the joint plate 9 is attached to the tension reinforcing plate 4. It is effective to set the number including the high-strength bolts for mounting so that it can support all loads.

As described above, the tensile load applied to the tensile reinforcing plate 4 must be set higher than the planned amount. now,
The amount of deformation generated in the tensile reinforcing plate 4 by applying the post tension load P to the tensile reinforcing plate 4 is represented by ΔL.
Further, as shown in FIG. 6, the center position of the joint plate 9 (the center of gravity of the high-strength bolts 8, 8, 8, 8) and the splicing bolts 7A, 7A, 7A for fastening the one end portion 4a of the tension reinforcing plate, The distance between the center of gravity of 7A and the center of gravity is represented by L, and a high-strength bolt 45A for fastening the central position of the joint plate 9 and the end portion 4b of the tension reinforcing plate,
When the distance between the center of gravity of 45A, ... And the center of gravity is represented by D, the following equation (1) is established. Here, E is the elastic modulus of the tensile reinforcing plate 4, and A is its cross-sectional area.

[0034] P = E ・ A ・ ΔL / L (1)

When the end plate 4b of the tension reinforcing plate is fastened to the lower flange 1c and the joint plate 9 is removed from the end 4b,
It is assumed that the post tension load is reduced to the value P ′ and balanced. Considering that the total amount of deformation of the tensile reinforcing plate 9 has not changed, a large error does not occur. At this time, the lowered post tension load P ′ is expressed by the following equation (2).

[0036] P '= E ・ A ・ ΔL / (L + D) (2)

From the above equations (1) and (2), the following relational equation (3) is established.

[0038] P '= P · L / (L + D) (3)

The same relational expression as the above expression (3) can be applied to the lower flange subjected to compressive deformation. Therefore, a tensile load of (L + D) / L times the predetermined amount of post tension load may be applied to the tensile reinforcing plate located at the end.

Next, when a wide reinforced girder such as a box girder is reinforced, the reinforced area becomes large, and accordingly, a wide post tension reinforcing plate and a large post tension load are required. There are also cases where a jack having a relatively small jack capacity is used or the construction is simplified. Therefore, in such a case, it is preferable to divide and set the lower surface of the reinforced girder into a plurality of reinforced regions in the direction perpendicular to the girder row, and introduce post tension into the reinforced girder for each reinforced region.

As a specific example, as shown in FIG. 8 (a), two reinforcing regions are set in parallel on the lower surface of the lower flange 50 of the H-shaped girder on both sides of the web, and posts are formed in each reinforcing region. Tension reinforcing plates 51A, 52A, 5
3A and post tension reinforcing plates 51B, 52B, 53B
There is one in which and are arranged in parallel. The post tension reinforcing plates arranged in series in each reinforcing region, such as the reinforcing plates 51A, 52A and 53A, are
The lower flange 50 is connected with the connecting bolts 56 and 58 via 55A and the like, and is fastened to the lower flange 50. In addition, as another specific example, as shown in FIG. 8B, a large number of divided reinforcement regions are provided in parallel on the lower surface of the wide lower flange 60 in the direction perpendicular to the girders, and each reinforcement region is provided. Post tension reinforcing plates 61A to 61F, 62A to 62
There is one in which F and 63A to 63F are arranged in parallel. Note that, as in FIG. 8A, post-tension reinforcing plates arranged in series in each reinforcing region, for example, reinforcing plates 61A,
62A, 63A and the like are connected to each other by using attachment bolts 66, 67 and the like via attachment plates 64A, 65A and fastened to the lower flange 60.

By adopting such a construction method, it becomes possible to easily adjust the post tension load for each reinforcing region and reduce the eccentric load applied to the reinforcing girder. Further, since a plurality of post tension reinforcing plates are used, the weight of one post tension reinforcing plate is reduced and a tensile load can be applied by a jack having a comparatively small jack capacity, so that the construction can be executed very easily.

Incidentally, in the construction method in which the reinforcing regions are divided and set in parallel in this way, the post tension load of the reinforcing plate in which the post tension is introduced in the first reinforcing region is the post tension load in the other reinforcing regions after that. The girder deteriorates due to compression and bending deformation. When a predetermined post tension load is introduced into the post tension reinforcing plates in the entire reinforcement region at the first time and then the post tension load decreased after the second time is increased to a predetermined value, a strictly predetermined value is obtained. Such an operation is not practical because it requires an infinite number of operations before reaching. Therefore, it is practical to set the load to be introduced into the post-tension reinforcing plate in the first reinforcement region to a slightly higher value, and complete the introduction of the load into the post-tension reinforcing plate in all reinforcement regions with a few operations. is there.
In this case, the calculation of the introduction load amount becomes a little complicated, so it is preferable to calculate the set value before the construction.

By the way, it is general to use a high-strength bolt as the splicing bolt. The splicing bolt receives a bending load during the above post tension introduction process, but if this bending load is excessive, after the post tension is introduced, due to the large axial force due to friction welding, the yield point will be exceeded and excessive plastic deformation will occur. It may be awakened and destroyed. As a result of an experiment in which a strain gauge was actually attached to the splicing bolt, it was confirmed that excessive plastic deformation does not occur if the bending load is within the elastic deformation range of the splicing bolt. This excessive plastic deformation is more likely to occur as the thickness of the reinforced flange, splicing plate, and stiffening plate increases, so the splicing bolt is selected with appropriate strength and bolt length so as not to exceed the yield point. Use one. Examples of such splicing bolts include high-strength hexagon bolts and torcia-type high-strength bolts suitable for friction welding, and their nominal dimensions are M16, M20, M22,
M24 is preferable, and the grade thereof is F8T, F10T for high strength hexagon bolts, and S10T for torcia type high strength bolts. A torque wrench, an electric or hydraulic tightening machine may be used for tightening the splicing bolt, and an electric impact wrench may be used for primary tightening.

As the post tension reinforcing plate and the tension reinforcing plate, those having a cross-sectional shape and rigidity corresponding to the shape of the flange to be reinforced and the desired post tension load are appropriately selected. This makes it possible to reinforce a desired portion of the bridge girder with a desired post-tension load, increase the rigidity of the bridge girder, and increase the fatigue strength. As such a reinforcing plate, specifically, a steel material is preferable from the viewpoint of easy availability, and a plate material carrying carbon fibers or aramid fibers with a resin binder is preferable from the viewpoint of light weight and high strength. Wherein the steel alloy containing iron and carbon, such as tensile strength 50 kgf / mm ² or more high tensile steel, the tensile strength be used in bridges due to the low 60 kgf / mm ² or more heat-treated steel or weldability less Further, a steel material having a higher tensile strength, a weather resistant steel material to which a metal element such as copper or chromium is added can be used. Further, when using a plate material carrying a carbon fiber or an aramid fiber with a resin binder as a reinforcing plate, it is necessary to bond the reinforcing plate to the reinforced girder with an epoxy resin or the like before connecting the reinforcing plate with the splicing bolt. It is preferable because it can be easily friction-bonded with a nut.

[0046]

EXAMPLES Hereinafter, more specific examples according to the present invention will be described, but the following examples do not limit the present invention in any way.

With the structure shown in FIG. 1 and FIG. 2, an H-section steel (shape dimension: H400 × 20) of rolled steel for general structure is used.
0x8x13; material: SS400 material, tensile reinforcing plate 4 and post-tension reinforcing plate 3 (shape dimension: width 200 m)
m, thickness 9 mm; material: SS400 material), using center hole jacks 10 and 11, when a jack load is applied to the tensile reinforcing plate 4 of the section 1 through the joint plate 9, the tensile reinforcing plate 4 of the section 1 is applied. The tensile stress acting (“section 1 reinforcing plate stress”) and the tensile stress acting on the post-tension reinforcing plate 3 in section 2 (“section 2 reinforcing plate stress”) were measured. The results are shown in FIG. 9 (Example 1) and FIG. 10 (Example 2). The numbers attached to the respective measurement points in FIGS. 9 and 10 indicate the measurement numbers.

(Embodiment 1) As shown in FIG. 9, the splicing bolts 7A, 7A, ... Are lightly tightened (tightening torque 370).
(kgf · cm) to the measurement points 1 to 11 obtained by gradually increasing the jack load, the tensile stress introduced to the post tension reinforcing plate 3 (section 2 reinforcing plate stress) is the tensile stress introduced to the tensile reinforcing plate 4. The stress (section 1 reinforcement plate stress) is considerably lower, and at measurement point 11, it is 3 of the section 1 reinforcement plate stress.
Only 8%. Next, at the measuring point 12, the splicing bolt was loosened (no tightening torque). At the measurement point 12, the frictional resistance force as described above with reference to FIG. 3A is released, and the tensile stress acting on the post tension reinforcing plate 3 (section 2 reinforcing plate stress) becomes the value of section 1 reinforcing plate stress. You can see that they are approaching dramatically. At measurement point 13 obtained by further increasing the jack load, the section 2 reinforcing plate stress was 96% of the section 1 reinforcing plate stress.

(Embodiment 2) As shown in FIG. 10, the splicing bolts 7A, 7A, ... Are lightly tightened (tightening torque 37).
(0 kgf · cm) to the measurement points 1 to 11 obtained by gradually increasing the jack load, the tensile stress introduced to the post tension reinforcing plate 3 (section 2 reinforcing plate stress) is the tensile stress introduced to the tensile reinforcing plate 4. It is much lower than the stress (stress of section 1 reinforcing plate). Next, it is the measurement point 12 that the splicing bolt is loosened (no tightening torque), and then the nuts 7B, 7B, ...
It was the measurement point 13 that the hammer was hit twice. At the measurement point 13, the frictional resistance force as described above with reference to FIG. 3A is released, and the tensile stress acting on the post tension reinforcing plate 3 (section 2 reinforcing plate stress) is substantially equal to the section 1 reinforcing plate stress. You can see that At the measurement points 14 and 15 obtained by further increasing the jack load, the section 2 reinforcing plate stress was approximately equal to the section 1 reinforcing plate stress.

From the above results, it is possible to introduce a post tension into the bridge girder by using the reinforcing plate, loosen the tightening torque of the splicing bolt, and add a hammering operation.
It was shown that a post tension load approximately equal to the jack load can be applied to the bridge girder. Furthermore, the change over time of the post tension load introduced to the bridge girder (change over one month)
As a result of the examination, it was confirmed that the bridge girder hardly changed even when a live load was repeatedly applied.

[0051]

As described above, according to the bridge reinforcing method of the first aspect, the post tension reinforcing plate is disposed on the lower surface of the reinforcing girder, and one end of the post tension reinforcing plate is attached to the reinforcing girder. Fixed to the post tension reinforcing plate, a tension reinforcing plate is arranged in series in the girder row direction on the lower surface of the girder to be reinforced so that it is close to the other end of the post tension reinforcing plate, and the other end of the post tension reinforcing plate and the tension At the same time as connecting one end of the reinforcing plate with a bolt and a nut via a splicing plate and attaching it to the girder to be reinforced, after that, applying a tensile load to the other end of the tensile reinforcing plate, the tensile reinforcing plate and the post. By the shearing force acting between the tension reinforcing plate and the splicing plate, the tensile load is transmitted to the post tension reinforcing plate, and after reaching a predetermined tensile load, the other end of the post tension reinforcing plate is Complement Since it is fixed to the girder, by adjusting the magnitude of the tensile load, the desired tensile load can be transmitted to the post tension reinforcing plate through the tension reinforcing plate and the splicing plate, and the post tension can be introduced into the reinforced girder. It is possible to increase the rigidity of the bridge, improve the fatigue strength, and provide reinforcement without sacrificing the additional space such as piping. In addition, the live and dead loads are the largest among the reinforced girders. It is possible to selectively reinforce the site of action with the desired prestress. Furthermore, since the post tension reinforcing plate and the tension replenishing plate are connected to each other and attached to the lower flange by using the bolt and the nut, it is possible to prevent the strength from being deteriorated due to the welding because no advanced welding work is required.

According to the reinforcing method of the second aspect,
After the post tension is introduced into the reinforced girder, the tension reinforcing plate is used as a new post tension reinforcing plate.
By repeatedly applying the described procedure, it becomes possible to dispose a plurality of post tension reinforcing plates in series on the lower surface of the reinforced girder and continuously reinforced the reinforced girder in the girder row direction.

According to the reinforcing method of the third and fourth aspects, in the step of transmitting the tensile load to the post tension reinforcing plate, (1) the other end of the post tension reinforcing plate and the tensile reinforcing plate are By applying an impact load to the bolts, nuts, or splicing plates used to connect the ends to each other, or (2) loosening the tightening torque of the bolts, a tension reinforcing plate and a post tension reinforcing plate can be obtained. It becomes possible to release the frictional resistance force acting on the contact surface between the reinforced girder and the splicing plate and smoothly raise the tensile load to apply a desired tensile load to the post tension reinforcing plate.

According to the reinforcing method of the fifth aspect, a tensile load can be applied to the other end of the tensile reinforcing plate by using a jack. According to the reinforcing method of the sixth aspect, the tension of the jack is increased. By connecting the rod and one end of the tension reinforcing plate via the joint plate, it is possible to smoothly transfer the jack load to the post tension reinforcing plate.

According to the reinforcing method of the seventh aspect,
In the step of transmitting a tensile load to the post tension reinforcing plate, a bolt having a diameter smaller than that of the bolt hole of the reinforced girder is used as a bolt connecting the other end of the post tension reinforcing plate and one end of the tensile reinforcing plate. Since a tensile load is applied to the post tension reinforcing plate in this state, the tensile load is smoothly transmitted to the post tension reinforcing plate without the shaft portion of the small diameter bolt hitting the wall surface of the bolted hole of the reinforced girder. , Since the bolt is replaced with a drift pin, the deviation between the bolt hole of the girder to be reinforced and the bolt hole of the reinforcing plate is corrected, and the drift pin is replaced with a bolt having a diameter larger than that of the small diameter bolt. Since a tensile load is applied to the post tension reinforcing plate, it is possible to reliably prevent the large diameter bolt shaft from hitting the wall surface of the bolt hole of the reinforced girder. It is.

Further, according to the reinforcing method of claims 8 and 9, after the predetermined tensile load is transmitted to the post tension reinforcing plate, the post tension reinforcing plate is welded to the reinforced girder or high strength is applied. Since it is fixed by using bolts or is fixed by adhesive, shear force is smoothly transmitted between the post tension reinforcing plate and the girder to be reinforced, especially the girder in which the acting bending moment in the reinforced section changes greatly. It becomes possible to enhance the reinforcement effect in the bridge.
Further, in the case of adhesive fixing, even if there is a camber on the reinforcement girder, a gap is prevented from being formed between the reinforcement girder and the post tension reinforcing plate, which is advantageous in terms of corrosion protection.

According to the reinforcing method of the tenth aspect, the lower surface of the reinforced girder is divided into a plurality of reinforced regions in the direction perpendicular to the girder rows, and post tension is introduced into the reinforced girder for each reinforced region. Therefore, since the tensile load per one time is small, it is possible to use a jack having a small jack capacity, and the weight of one post tension reinforcing plate can be small, so that the construction is extremely easy. Particularly when reinforcing a wide girder to be reinforced, it is possible to reduce the eccentric load by adjusting the post tension load in each reinforcing range.

[Brief description of drawings]

FIG. 1 is a schematic view showing an embodiment of a bridge reinforcing method according to the present invention.

FIG. 2 is a bottom view of FIG.

FIG. 3A is a post-tension reinforcing plate that is bent and deformed by frictional resistance acting on the contact surface between the post-tension reinforcing plate and the lower flange and the contact surface between the post-tension reinforcing plate and the splice plate. And (b) is a schematic cross-sectional view showing a state in which the bending deformation is eliminated after an impact load is applied to the nut.

FIG. 4 is a schematic view showing a state in which a post tension reinforcing plate and a lower flange are bonded with an adhesive and pressure-bonded with a spring clip.

FIG. 5 is a schematic view showing a lower flange continuously reinforced using a plurality of post tension reinforcing plates.

FIG. 6 is a schematic view showing a state in which a post tension reinforcing plate receives a tensile load.

FIG. 7 is a schematic view showing a state in which the end portion of the tensile reinforcing plate is fastened to the lower flange.

FIG. 8 is a schematic view showing a lower flange reinforced by arranging a plurality of post tension reinforcing plates in parallel.

FIG. 9 is a graph showing a correspondence relationship between tensile stress applied to each reinforcing plate in section 1 and section 2.

FIG. 10 is a graph showing a correspondence relationship between tensile stress applied to each reinforcing plate in section 1 and section 2.

FIG. 11 is a schematic diagram for explaining a stress applied to a bridge girder.

FIG. 12 is a schematic diagram for explaining a conventional post-tensioning method using an outer cable.

[Explanation of symbols]

1 Bridge girder (main girder) 1a Upper flange 1b web 1c Lower flange 3 Post tension reinforcing plate 3a One end of post tension reinforcing plate 3b The other end of the post tension reinforcing plate 4 Tension reinforcing plate 4a One end of tensile reinforcing plate 4b The other end of the tension reinforcing plate 4A high strength bolt 4B nut 5 Saddle plate 6A, 6B splicing plate 7A splice bolt 7B nut 8 volt 9 Joint plate 10, 11 Hydraulic center hole jack 10a, 11a tension rod 10a ', 11a' tension rod 12 jack fixing jig 12a, 12b Jack fixing jig fixing part 13A high strength bolt 14, 15 Direction to apply impact load 16, 17 Direction to apply impact load 21 Post tension reinforcement plate 22 Adhesive 23 spring clips 30, 31, 32 Post tension reinforcement plate 32a End of post tension reinforcing plate 33, 34A, 34B, 35, 36A, 36B Splicing plate 37A, 38A, 39A bolts 37B, 38B, 39B nuts 40 Post Tension Reinforcement Plate Bolt Hole 41 Lower flange bolt hole 42 Bolt holes for tensile reinforcement plate 43 Lower flange bolt hole 44 Bolt hole of tensile reinforcement plate 45A bolt 45B nut 46 Post Tension Reinforcement Plate Bolt Hole 47 Lower flange bolt hole 50 lower flange 51A, 52A, 53A Post tension reinforcement plate 51B, 52B, 53B Post tension reinforcement plate 54A, 54B Splicing plate 55A, 55B Splicing plate 56,57,58,59 Splice bolt 60 lower flange 61A-61F Post tension reinforcing plate 62A-62F Post tension reinforcing plate 63A to 63F Post tension reinforcing plate 64A-64F, 65A-65F Splicing plate 66,67 Splice bolt 70 bridge girder 70a Upper flange 70b web 70c Lower flange 71 Compressive stress 72 Tensile stress 80 bridge girder 80b web 80c Lower flange 81,82 saddle 83,84 Fastener 85 Outer cable

─────────────────────────────────────────────────── --- Continuation of the front page (56) References JP-A-4-285247 (JP, A) JP-A-11-190009 (JP, A) JP-A-3-151403 (JP, A) JP-A-9- 100513 (JP, A) JP-A-1-318608 (JP, A) JP-A-52-130127 (JP, A) JP-A-4-124351 (JP, A) (58) Fields investigated (Int.Cl. ⁷ , DB name) E01D 22/00 E01D 21/00 E01D 19/00 E01D 1/00

Claims (10)

(57) [Claims] 1. A post tension reinforcing plate is disposed on the lower surface of a girder to be reinforced of a bridge, and one end of the post tension reinforcing plate is fixed to the girder to be reinforced, and is close to the other end of the post tension reinforcing plate. In this way, the tension reinforcing plates are arranged in series in the girder row direction at appropriate places on the lower surface of the girder to be reinforced, and the other end of the post tension reinforcing plate and one end of the tensile reinforcing plate are connected via a splicing plate with bolts and nuts. At the same time connected to the reinforcement girder by connecting using, after applying a tensile load to the other end of the tensile reinforcing plate, the tensile reinforcing plate and the post tension reinforcing plate and the splicing plate via the bolt The tensile load is transmitted to the post tension reinforcing plate by a shearing force applied between the post tension reinforcing plates, and after reaching a predetermined tensile load, the other end of the post tension reinforcing plate is fixed to the reinforced girder, For reinforcement girder A bridge reinforcement method characterized by introducing post tension. 2. After introducing a post tension into the reinforced girder, the tension reinforcing plate is used as a new post tension reinforcing plate, and the procedure according to claim 1 is repeatedly applied, and a plurality of post tension reinforcing plates are used. The bridge reinforcing method according to claim 1, wherein the reinforced girder is continuously reinforced. 3. A bolt, nut or splice used to connect the other end of the post tension reinforcing plate and one end of the tensile reinforcing plate in the step of transmitting a tensile load to the post tension reinforcing plate. The bridge reinforcing method according to claim 1 or 2, wherein an impact load is applied to the plate. 4. The tightening torque of a bolt used to connect the other end of the post tension reinforcing plate and one end of the tensile reinforcing plate in the step of transmitting a tensile load to the post tension reinforcing plate. The method for reinforcing a bridge according to claim 3, which is loosened. 5. The method for reinforcing a bridge according to claim 1, wherein a tensile load is applied to the other end of the tensile reinforcing plate using a jack. 6. The method of reinforcing a bridge according to claim 5, wherein the tension rod of the jack fixed to the reinforcement girder and the other end of the tension reinforcing plate are connected via a joint plate. 7. A bolt for connecting the other end of the post tension reinforcing plate and one end of the tensile reinforcing plate in the step of transmitting a tensile load to the post tension reinforcing plate, as compared with a bolt hole of a reinforced girder. Then, using a small-diameter bolt, transmit the tensile load to the post tension reinforcing plate in this state, then replace the small-diameter bolt with a drift pin, and then replace the drift pin with a larger-diameter bolt than the small-diameter bolt. 7. The method for reinforcing a bridge according to claim 1, wherein the tensile load is transmitted to the post tension reinforcing plate in this state. 8. After transmitting a predetermined tensile load to the post tension reinforcing plate, the post tension reinforcing plate is fixed over the entire length in the girder direction or partially using welding or high-strength bolts. The method for reinforcing a bridge according to any one of claims 1 to 7, wherein post tension is introduced into the girder to be reinforced. 9. After transmitting a predetermined tensile load to the post tension reinforcing plate, the post tension reinforcing plate is adhered to a reinforcement beam, and then the other end of the post tension reinforcing plate is attached to the reinforcement beam. The bridge reinforcing method according to any one of claims 1 to 7, wherein the bridge is fixed and post tension is introduced into the reinforced girder. 10. A reinforcing member, wherein the lower surface of the reinforcing girder is divided into a plurality of reinforcing regions in the direction perpendicular to the girder row, and post tension is introduced into the reinforcing girder for each reinforcing region.
The method for reinforcing a bridge according to any one of 1.