KR101163456B1 - The splicing method of segmental prestressed concrete box beam - Google Patents

Abstract

PURPOSE: A segmental prestressed concrete box beam and a joint method thereof are provided to prevent the total compressive stress of concrete joined to a space retainer from exceeding allowable compressive stress. CONSTITUTION: A joint method of a segmental prestressed concrete box beam is as follows. Space retainers(10), made of a material having strength lower than the strength of hardened epoxy, are installed between the joint surfaces of a pair of segments(S). Epoxy is spread on the joint surfaces of the segments. The segments are pressed in a direction facing each other. The epoxy is cured. Tendons are inserted into tendon ducts(200) and tensed.

Description

Segmented prestressed concrete box beam and joining method {The splicing method of segmental prestressed concrete box beam}

The present invention relates to a segmented prestressed concrete box beam and a joining method thereof, and to a segmented prestressed concrete box beam and a joining method configured to solve a stress concentration problem occurring when joining segments to each other.

Epoxy Bonded Segment Girder is a method of prestressed concrete girder, which is divided into several segments and manufactured at the factory or workshop and then transported to the site where the girders are installed. A bridge construction method of joining segments with epoxy and tensioning a tendon in the longitudinal direction of a girder to form an integral prestressed concrete girder.

The segment joining method of the PSC girder segmentation method includes the field casting joining method of placing concrete or mortar and joining the segments in the field, and the contact joining method of joining the segments in close contact. Contact bonding methods include an epoxy joint method in which an adhesive such as epoxy is applied between segments, and a dry joint method in which segments are joined only by the tension force of the tendon without the adhesive. In situ splice method, it is not necessary to match the shape of the joint surface because the joints are placed at intervals, the reinforcement joints and tendon duct joints are placed, and then the joint concrete is poured. On the other hand, the contact joining method should coincide with each other so that the joint surfaces of both segment joint ends that are in close contact are evenly contacted. Therefore, a method of precisely matching the joint surface by matching casting the segment is mainly used. In the matchcasting method, the first segment A is first manufactured using the formwork 1 as shown in FIG. 1A, and the segment A is produced when the segment B to be joined to the prefabricated segment A as shown in FIG. 1B. ) Is a method of making a segment to make a perfect joint surface by placing concrete in the space between the formwork (1) and the segment (A) by utilizing the joining formwork. When the new segment B is completed, the segment A used as formwork is transported to the reservoir and the new segment B is used as the joint formwork of the next segment. This matchcasting method is rather cumbersome but can produce girder segments with precisely matched joints.

The epoxy joining method is easier to join and shorten the air than the cast-in-place method. However, even if the segment joining surface has a complicated shape such as shear key, guide key, and tendon duct, the uneven part must be precisely matched. Segment creation is very tricky. In addition, the girder longitudinal reinforcing bars are disconnected at the joint to form discontinuity, and due to manufacturing errors, improper mixing and application of epoxy, misalignment of segments during joining, and uneven joint pressure, only a part of the joint surface is contacted at the joint. Pressure concentrations can cause unintended stress concentrations at the joints, resulting in structurally weak parts. However, when epoxy is used for the bonding surface, the micro-gap between the bonding surface caused by fabrication error and bonding error can be completely filled, and stress concentration no longer occurs when prestress is introduced by tension of tendon after curing of epoxy. Does not occur. Therefore, in the case of using the epoxy bonding method, it is better to bond at a lower pressure if possible, and then to integrate the segments with a large tension force after curing of the epoxy.

Segmental method is a segmental method that divides the girder into a large number of short segments, such as a segmental PSC box girder bridge that constitutes a bridge of span with a single girder that covers the entire bottom plate. A bridge can be divided into a spliced girder method, which is made by dividing a girder into a small number of long segments, such as a segmented PSC box beam consisting of several girders with small cross sections. The PSC box girder and the PSC box beam are somewhat confusing because they are structurally composed of words with the same meaning. The box girder has a wide top flange including the cantilever section that forms the full width of the bottom plate, and the cross section is very large and inside the box It is possible to input manpower and equipment, and it is possible to tension the tendons inside the girder. The box beam has a rectangular shape and has a small cross section, thereby reducing the weight of the girder by forming a hollow part with EPS or wood formwork buried inside the box. Box girders are usually used for bridges with spans longer than 50m and box beams are usually used for bridges with spans less than 40m. The box beam is also used for the girder bridge, so it is a kind of girder which means a big beam, but to distinguish it from the box girder, the word beam is used. In the segmental method, the cross section of the girder is usually very large and the segment length is generally much shorter than the maximum dimension of the segment section due to the limitation of the carrying weight. In addition, when a segment is joined, a specially constructed launching girder or erection girder is installed in the substructure, and the segment is placed on the temporary girder, or suspended on the temporary girder, and the weight of the segment affects the behavior at the time of joining. Joining the segments one by one by applying a relatively low joining pressure by means of a joining steel bar without the use of. On the other hand, in the segmental girder method, since the cross section of the girder is small, the length of the segment is long, and it is common to join in a state where only both ends of the segment are supported on the ground using a simple assembly table.

2a to 2c is an exemplary view showing a segment assembly process of the segment girder method. As shown in Fig. 2a, the segment S of the girder is installed on the assembly table C, and a portion T of the tendon is inserted. When the tendon is ready for tension, epoxy is applied to the joint. When the application of the epoxy is completed, as shown in Figure 2b the tendon (T) by using a tension jack (J) of the tension to close the segment (S). During the process of joining the segment S, a sliding plate or the like must be provided at the point of the segment so that the segment S can move freely in the horizontal direction. In order to join the girder segment, a steel bar for joining or the like may be separately installed, and a part of the tension tendon may be used in the joining to reduce the cost. After a certain curing time, when the epoxy reaches a predetermined strength, as shown in FIG. 2c, the remaining tendons (T) are inserted and the tension tendons (T) are alternately inserted using the tension jack (J) to complete the PSC girder. . When the tension of the tendon is completed, upward rise occurs, and the finished girder is supported only by the end assembly. The most important process in the above process is a joining process. In the case of epoxy bonding, a dense epoxy layer is formed only by applying a certain pressure to squeeze the epoxy coated on the bonding surface. However, when joining, segment alignment error occurs inevitably due to deflection due to the weight of the segment, installation error of assembly table, temperature difference in the cross section, and so on. Even if manufactured, the pressure is concentrated only on a part of the joint surface. An easy way to solve this problem is to install guide keys and the like on the mating surface and join them with great force to force the segments to be aligned. To this end, in addition to the free movement on the horizontal plane required for the movement of the segment during the joining process, it is necessary to support the point of the segment with rubber or plywood, so that the segment can be moved up and down with a certain degree of flexibility. Of course, if you apply tension to the bonded girders so that the rise occurs, you do not need the flexibility to move up and down the segment points of the intermediate assembly, but this tension should normally exert a very large force that must tension more than half of the entire tendon. Therefore, there is a great possibility of problems due to stress concentration during the joining process.

In addition, in order to cure the epoxy and reach a predetermined strength after completion of the bonding, curing time of 8 hours or more is usually required. Therefore, it is common work practice to join the work weekly and to work the tension the next day. Therefore, there is usually a time difference of more than 12 hours from joining to introduction of tension, during which there is a daily cross of temperature. In Korea, a crossover of more than 10 ℃ is very common in spring and autumn. When a crossover occurs, a temporary temperature difference occurs in the transverse direction perpendicular to the vertical and horizontal directions of the girder, that is, the length of the girder. Will be bent. FIG. 3A is a diagram exaggerating somewhat to show a deformation of an unbonded segment due to a difference in temperature between the segments. The angle of rotation of the segment ends, i.e., the joints, increases as the temperature difference increases, and as the segment length increases. In general, the temperature of the upper part of the girder is higher than the lower part in the daytime, and the lower temperature is higher than the upper part in the morning due to the geothermal heat. Thus, this deformation can occur in the opposite direction in theory. In the left and right directions also shows a similar aspect as shown in Figure 3b. In the current specification, it is prescribed to prepare for one crossover of max. 15 ℃, but when the temperature difference of 15 ℃ occurs up and down, left and right of the girder, if the bonding force is small, the segments joined as shown in FIGS. 3A and 3B become simple beam structures. The distance between the faces, i.e. the thickness of the epoxy layer, changes significantly during curing, which can cause problems. Therefore, in order to minimize such a change in the thickness of the epoxy layer, it is necessary to maintain a relatively large bonding force so that each segment does not behave individually but has continuous beam behavior as an integral girder bonded to each other. 4A and 4B show the behavior of the continuous beam structure when the vertical temperature difference and the left and right temperature difference occur, respectively. In FIG. 4A, the end point slightly rises and the middle point slightly sags because the reaction force of the intermediate point increases and the reaction force of the end decreases when the continuous beam structure is obtained. The deformation due to the left and right temperature difference is as shown in Fig. 4b if the friction coefficient of the sliding plate at the point is small and the horizontal displacement is free. Depending on the support conditions of the segments at the time of joining, the joining force required for continuous beam behavior is surprisingly large, and in the case of a segmented PSC box beam of 30m length, sometimes a large joining tension of about 170ton or more is required. However, in order to apply such a large tension force at the time of joining, the joining surface must be very precisely matched. If the joint surface is not precisely matched and such a large bonding force is applied only to the contact surface of a small area, a large pressure is applied only to the contact portion, so that partial fracture such as local split cracking or spattering occurs. Even if the problem does not occur at the time of joining, the stress concentration phenomenon at the time of joining remains, so it may cause a problem at the tension in addition to the prestress added at the tendon tension of the girder. 5A and 5B are examples of split cracks and dropouts occurring in the prestress introduction step due to stress concentration at the time of segment joining, respectively.

Also, at present, a matchcasting method such as the method illustrated in Fig. 1B is known as a method of making the most precisely matched joint surface. However, the matchcasting method creates segments sequentially, which increases production time and costs.

The present invention was derived to solve the problems of the techniques that are the background of the present invention, the problem to be solved by the present invention can effectively solve the stress concentration problem occurring in the segment joining process of the segment girder in the prestressed concrete segment girder method A segmented prestressed concrete box beam and its joining method are presented.

The present invention as a means for solving the above problems,

In the segmented prestressed concrete box beam and the joining method thereof,

A spacing member installation step of installing a spacing member of a material having ductile stiffness than the stiffness of the cured epoxy between two joining surfaces of the pair of segments to be joined;

An epoxy coating step of applying epoxy to the joint surfaces of the pair of segments to be bonded in the state where the spacer is installed;

When the gap retaining material is installed and the epoxy is coated, the applied epoxy is squeezed by applying the bonding pressure in the direction in which the segments to be bonded are close to each other. Bonding to form a tight epoxy layer by filling with the epoxy;

An epoxy curing step of curing the epoxy while maintaining the bonding pressure after the bonding step;

A prestressing step of tensioning the tendon by inserting the tendon after the curing of the epoxy is completed; , ≪ / RTI &

After the deformation of the spacer retained by the pressure in the bonding step, the thickness is smaller than the coating thickness of the epoxy but larger than the maximum error in the normal direction of the bonding surface so that a tight epoxy layer is formed between the bonding surfaces and the bonding surface of the segment to be bonded is Do not directly contact, and by using a gap retaining material of a material less rigid than the rigidity of the cured epoxy to lower the pressure applied to the gap retaining material in the prestressing step after curing the epoxy to the gap retaining material in the bonding step and the prestressing step The present invention provides a segmented prestressed concrete box beam, and a method of joining, wherein the sum of the acting pressures is smaller than the allowable compressive stress of the joint.

An expansion joint construction step of constructing an expansion joint that has a predetermined thickness and an area in each of the portions to be joined and has a predetermined thickness and area, and when the opposite surfaces of the segments are joined, and which is expanded into the box. ; More,

It is preferable to attach the gap retaining member to the enlarged joint part in the gap retaining member installation step, and to apply the epoxy to the enlarged joint part in the epoxy coating step.

As the gap retaining material, a rubber having a larger area than the thickness can be used.

Exposing some reinforcing bars on top of the junction in the manufacture of said segments,

In the bonding step, it is preferable to press some of the reinforcing bar disposed on the upper part of the segments to be bonded to each other with a coupler in a direction close to each other.

Inserting an anchor bolt, part of which is exposed to the upper side of the joint side during the manufacture of the segments,

And further comprising a bonding device for installing a fixing plate fixed to the anchor bolt by the first nut and the both ends are coupled to the fixing plate by a second nut and the rod-shaped computer screw disposed in the longitudinal direction of the box beam ,

In the bonding step, the second nut may be rotated to press the segments in a direction adjacent to each other.

Further, according to the present invention,

For segmented prestressed concrete box beams,

A pair of segmented prestressed concrete boxbeam segments joined together;

It is applied to the joint surface of the pair of segments, and squeezed by the application of the bonding pressure in the direction in which the segments are close to each other in the gel state before curing, the gap excluding the gap retaining material among the gaps between the joint surfaces of the segments. Epoxy cured in a tightly filled state;

The thickness after deformation by the joining pressure is smaller than the coating thickness of the epoxy so as to be attached to any one of the joining surfaces of the pair of segments and not directly contact the joining surfaces of the segments when the joining pressure is applied. Spacing retaining material larger than the normal maximum error of the joining surface of the electrodes; , ≪ / RTI &

The spacer is composed of a material having a stiffness than the rigidity of the cured epoxy, and when the prestress is applied to the segments after curing the epoxy to lower the pressure acting on the spacer maintaining the bonding pressure and prestress Segmented prestressed concrete box beam is characterized in that the sum of the pressure acting on the spacer in the process is less than the allowable compressive stress of the concrete of the joint of the segments.

Preferably, the segment further includes an enlarged joint portion having a predetermined thickness and area in each of the portions to which the segments are joined, which may be simultaneously joined when the opposite surfaces of the segments are joined, and enlarged into the box.

The gap retaining material may be a rubber having a large area compared to the thickness.

Further comprising a block-out portion provided on top of the joint side of the segments and a part of the concrete is removed,

Reinforcing bars which can be connected to each other by a coupler may be exposed to the block out part.

Anchor bolts are partially exposed on the upper side of the junction portion of the segments,

A fixing plate fixed to the anchor bolt by a first nut;

It may further comprise a temporary fixing means including a rod-shaped computer screw coupled to the fixing plate provided in the segments adjacent to each other by the second nut, respectively.

According to the present invention, when joining the segment girder segment, a flexible spacing member having a rigidity smaller than that of the cured epoxy is provided between the joining surfaces, and the epoxy is applied to a portion where the spacing member is not in contact with each other and the bonding force is applied. At this time, the final thickness of the spacer retained by the bonding force is larger than the maximum error in the normal direction of the joint, so that the joint does not come into direct contact, and epoxy is used by using the spacer having a sufficiently small rigidity compared with the rigidity of the cured epoxy. By increasing the stress of the spacer retained by the tension force acting after curing, the final compressive stress of the concrete in contact with the spacer is not exceeded the allowable compressive stress of the concrete so that local cracking or dropping due to stress concentration The present invention provides a segmented prestressed concrete box beam capable of preventing partial breakage of a joint and a method of joining the same. In addition, according to the present invention, since the joint surface does not directly contact when joining segments, a certain joint surface manufacturing error is tolerated, so that a method of manufacturing a match surface of a joint surface having a low working efficiency is not used to make a completely matched joint surface. It is possible to provide a segmented prestressed concrete box beam and a method of joining the same.

1A and 1B are diagrams for explaining a method of manufacturing a segment by matchcasting.
2A to 2C are views (side views) for explaining the assembling process of the segment girder;
3A is a diagram (side view) for explaining the bending deformation of a simple beam structure due to a difference in temperature between the segments.
3B is a view for explaining the bending deformation of the simple beam structure due to the left and right temperature difference of the segment (plan view).
4A is a diagram (side view) for explaining the bending deformation of the continuous beam structure due to the vertical temperature difference of the segment.
4B is a view for explaining the bending deformation of the continuous beam structure due to the left and right temperature difference of the segment (plan view).
Figure 5a is a photograph showing an example of splitting cracking occurred in the prestress introduction step due to stress concentration phenomenon at the time of segment bonding.
5b is a photograph showing an example of dropout occurring in the prestress introduction step due to stress concentration at the time of segment bonding;
6A is a cross-sectional view of a typical segmented prestressed concrete box beam.
6B is a side view of a three segment prestressed concrete box beam.
Figure 6c is a view for explaining an enlarged cross-section of the segmented prestressed concrete box beam according to the present invention.
Figure 7 is a view for explaining the step of installing the gap retaining material of the segmented prestressed concrete box beam and the bonding method according to an embodiment of the present invention.
8A and 8B are views for explaining the bonding step of the segmented prestressed concrete box beam and the bonding method according to one embodiment of the present invention.
9 is a view for explaining how the temporary fixing means of the present invention is installed.
10 is a view for explaining a state in which the temporary fixing means shown in FIG.
11 is a view for explaining a segment formwork system using a segment separator and a precision block.

Hereinafter, with reference to the drawings will be described the embodiment of the segmented prestressed concrete box beam and the bonding method according to the present invention to provide specific details for carrying out the present invention.

First, a segmented prestressed concrete box beam according to an embodiment of the present invention will be described.

Figure 6a is a cross-sectional view of a conventional segmented prestressed concrete box beam, Figure 6b is a side view of the three-segment prestressed concrete box beam, Figure 6c is a view for explaining an enlarged cross-section of the segmented prestressed concrete box beam according to the present invention, Figure 7 Is a view for explaining the step of installing a spacer maintaining the segmented prestressed concrete box beam and the joining method according to an embodiment of the present invention, Figure 8a and 8b is a segmented prestressed in accordance with one embodiment of the present invention It is a figure for demonstrating the bonding step of a concrete box beam and its joining method.

The segmented prestressed concrete box beam according to the present embodiment is a box beam segment (S), an epoxy (20), a spacer (10), an expansion joint (30), a block out portion (40), reinforcing bars 41 and reinforcing bars And a coupler 42.

The segment S is a girder structure segmented in a transportable unit and is bonded to each other to form a PSC box beam. The cross section of the box beam segment S is shown in FIG. 6A, which includes a tendon duct 200 and a hollow 300. Hollow portion 300 is usually formed by putting the EPS therein when manufacturing the segment (S). FIG. 6B is a side view of the three segment box beam and the segments S are connected in the form shown in FIG. 6B. In the present invention, the segment S is provided with an enlarged junction 30 as shown in FIG. 6C, wherein the enlarged junction 30 has a predetermined thickness and an area in each of the bonded portions of the segments S. It is an enlarged part of the inside of the box so that the opposite faces of the segment S can be joined at the same time as they are joined. The portion indicated by reference numeral A in FIG. 6C is a distal plane.

As shown in FIG. 7, the joint surface of the segment S is provided with a guide key 100, a tendon duct 200, and a block out part 40 from which a part of concrete is removed, and a block out part 40. Reinforcing bar 41 is exposed to the reinforcing bars 41 are connected to each other by a coupler 42 (see Fig. 8a), where the coupler 42 uses a product that can be tightened in the direction in which the reinforcing bars 41 are close to each other To provide a part of the bonding pressure of the segments. On the other hand, the reinforcing bar 41 is tension-connected by the coupler 42 may be a means capable of appropriately cope with the tensile force of the upper girder that may occur during the transport and construction of the integrated PSC box beam is completed tension. Therefore, the block out portion 40 is filled with non-shrink mortar before mounting the completed PSC box beam to the underlying structure.

The epoxy 20 is applied to the joint surface of the segment (S), and the segments are joined together while being squeezed as the joint pressure is applied in a direction in which the segments (S) are close to each other in a gel state before curing. Of the gaps between the bonding surface of the (S) is cured in a state in which the gaps except the gap retaining material (10) tightly filled.

8A and 8B are views illustrating a state in which a bonding pressure is applied while an epoxy 20 is applied. FIG. 8A is a sectional view showing a portion where the guide key 100 is located, and FIG. 8B is a sectional view showing a portion where the spacer 10 is attached.

The spacer 10 is attached to any one of the joint surfaces of the pair of segments S, and as shown in FIG. 7, the gap holder 10 has a rectangular cross section and has an enlarged joint 30. And a spacing member 10a attached to the spacing member 10a and a spacing member 10b having an annular cross section and attached to surround the tendon duct 200. The gap retaining material 10b surrounding the tendon duct 200 may serve as a dam to prevent the epoxy 20 that is squeezed when the bonding pressure is applied to the segment S from entering the tendon duct 200. .

The gap retainer 10 has a thickness smaller than the coating thickness of the epoxy after deformation by the joining pressure so that the joining surfaces of the segments do not directly contact when the joining pressure is applied to the segment S, and the maximum normal direction of the joining surfaces of the segments It is designed to be larger than this, and in this embodiment, a rubber having a large area compared to the thickness is used. In addition, the spacer 10 is composed of a material having ductile rigidity than the rigidity of the cured state of the epoxy 20 (rubber as in this embodiment), after the epoxy 20 is cured When the prestress is applied to the segments S, the pressure acting on the spacer 10 is reduced so that the sum of the pressure acting on the spacer 10 in the process of applying the bonding pressure and the prestress is the concrete of the joint of the segments. It is configured to be smaller than the allowable compressive stress of. Details thereof will be described in the description of the method of bonding the box beam.

9 and 10 illustrate a segmented prestressed concrete box beam in accordance with another embodiment of the present invention. The present embodiment is different from the previous embodiment in that the block-out part 40, the exposed reinforcing bar 41 and the coupler 42 are not provided, but the temporary fixing means 50 are included. do.

The temporary fixing means 50 is composed of an anchor bolt 51, a fixing plate 52, a computer screw 54.

The anchor bolt 51 is partially exposed on the upper surface of the junction side of the segment (S).

The fixing plate 52 is a plate fixed to the anchor bolt 51 by the first nut (53).

The threaded screw 54 is a rod-shaped configuration fixed to fixing plates provided on segments joined to both ends, respectively, and is coupled by a second nut 55 as shown in FIGS. 9 and 10. By rotating the second nuts 55 in a direction close to each other, the bonding pressure may be applied to the segments in the state where the epoxy 20 is applied. At this time, the nut that is relatively out of the second nut 55 is used to apply the bonding pressure and the inner nut is used to prevent the thickness of the epoxy layer from changing due to temperature change after the bonding pressure is applied.

Hereinafter, a preferred embodiment of the method of joining the segmented prestressed concrete box beam according to the above-described embodiment will be described.

The segmented prestressed concrete box beam and its joining method according to the present embodiment are composed of an expansion joint construction step, a gap retainer installation step, an epoxy coating step, an adhesion step, an epoxy curing step, and a prestressing step.

The expansion joint construction step is a step of constructing an expansion joint that can be joined at the same time when the opposing surfaces of the segment have a predetermined thickness and area to each of the portions to be bonded to the pair of segments to be bonded. 6C is an explanatory view for explaining the enlarged joint, and the portion indicated by A on the drawing is a far-end surface, and the portion indicated by 30 is hatched and is an enlarged cross-sectional portion.

The joints of the segments S are composed of two different materials, that is, the epoxy S 20 and the spacer 10, not directly contacting the segments S, so that disturbance of the stress flow occurs, Unexpected problems may also occur in the back, and part of the cross section may not be used effectively. One way to solve this problem is to enlarge the cross section of the junction. In general, the joints of the segments have a thin abdomen through which the tendon duct passes, which makes it difficult to pour and compact concrete, which may cause problems in the quality of the joint surface. However, in the present embodiment, by providing an enlarged cross section at the time of manufacturing the segment, it is easy to pour and compact concrete, thereby improving the quality of the segment joint end and increasing the joint area, thereby increasing the structural safety of the joint.

As shown in FIG. 7, the spacing member installation step may include any one of the joint surfaces, which are two surfaces to be joined, of the pair of segments to be joined (including the surface of the enlarged joint part 30). Attaching the spacer 10 of the material having a stiffness compared to the cured epoxy to the. In the present embodiment, a rubber having a larger area than the thickness is used as the spacer 10. The reason why the stiffness of the spacer 10 should be soft compared to the stiffness of the cured epoxy will be described later.

The gap retaining material 10 may have a constant thickness as shown in FIG. 7, but may have a cross section having a rectangular shape (a gap retaining material indicated by 10a), or may have a circular shape (not shown). It may be configured as an annular enclosing tendon duct 200 (spacing retaining material indicated by 10b), and the above-described shape may be configured in one or two or more combinations. On the other hand, the position where the spacer is installed may be a joint surface of the segment (S) or expansion joint 30, may be above the guide key 100, may be a position surrounding the tendon duct 200 as described above. have. When the gap retaining material is installed at the position surrounding the tendon duct 200, such as the gap retaining material 10 indicated by 10b in FIG. 7, it serves as a dam to prevent epoxy from flowing into the interior of the tendon duct 200. You can also do it.

The epoxy coating step is a step of applying the epoxy (20) to the bonding surface in the state that the spacer 10 is installed.

8A and 8B show that the bonding is performed with the epoxy 20 applied between the segments. FIG. 8A is a view for explaining a portion in which the guide key 100 is provided, and FIG. It is a figure for demonstrating the part in which the ash 10 was installed. In the case where the spacer 10 is attached as shown in FIG. 8B, it is preferable that the epoxy 20 is not applied between the spacer 10 and the segments. Of course, even if epoxy is applied to the spacer 10, since the epoxy is in a gel state in the bonding step, the epoxy is squeezed out while pressing the segments to be close to each other by the bonding pressure. I will have the same form as 8b.

The bonding step is a step of pressing the pair of segments in a direction adjacent to each other after the epoxy coating step, by using the coupler 42 shown in FIG. Will be provided. On the other hand, the bonding pressure of the bonding step may be made using some tension force of tendon. If part of the tendon can be used to uniformly apply the required bonding pressure to the shear surface, the bonding pressure by the coupler 42 may not be necessary. As described in the bonding step, a part of the gel-like epoxy is squeezed out of the joint surface to fill the gap between the segments tightly.

On the other hand, unlike in the present embodiment may be used as a temporary fixing means 50 as shown in Figure 9 and 10 as a means for providing a bonding stress in the bonding step. (The guide key 100 shown in FIG. 9 is a guide key in the shape of a groove into which the guide key shown in FIG. 7 can be inserted.) The configuration of the temporary fixing means 50 is a configuration of the segmented prestressed concrete box beam. Since only the mechanism for providing the joining pressure has already been described in the above description, a part of the joining pressure may be provided by rotating two pairs of second nuts 55 connected to the threaded screw 54 in a direction close to each other. .

The epoxy curing step is to cure the epoxy 20 in a state in which the segments are bonded with the gap retaining material therebetween in the bonding step.

The prestressing step is a step of introducing prestress into the girder by inserting a tendon (not shown) in the tendon duct 200 after the curing of the epoxy is completed and the tension force is applied to the tendon.

In the present invention, the gap retaining material 10 is provided between the joining surfaces, the epoxy 20 is applied to a portion where the gap retaining material 10 is not in contact, and the bonding force is applied to join the segments. In the bonding step, since the flexible spacing member 10 is sandwiched between the joining surfaces, the spacing member 10 receives most of the bonding pressure after the epoxy in the gel state is sufficiently squeezed by the bonding pressure. The flexible spacer 10 is compressed by the action of the bonding pressure and finally deformed to a predetermined thickness. The deformation thickness is greater than the sum of the fabrication error and the assembly error of the joint surface, so that the segment joint surface of the epoxy Avoid direct contact during curing time. That is, in the bonding step, most of the bonding force acts only on the portion in contact with the spacer 10. During the curing step, when the epoxy reaches the desired strength, the tendon is inserted and tensioned. However, if the stiffness of the spacer 10 in the prestressing step is sufficiently smaller than the stiffness of the cured epoxy 20, most of the tension force introduced in the prestressing step is the remaining portion except for the portion in contact with the spacer 10. It is delivered through a cross section connected to a layer of cured epoxy 20. Finally, in the bonding step and the prestressing step, the sum of the compressive stresses acting on the spacer 10 is limited to be within the allowable compressive stress of concrete. At this time, the allowable compressive stress of concrete refers to the allowable compressive stress of concrete based on road bridge design standard, concrete structural design standard, or railway bridge design standard.

This can be summarized as follows.

………………………식(1)

... ... ... ... ... ... ... ... ... Equation (1)

………………………………………식(2)

... ... ... ... ... ... ... ... ... ... ... ... ... ... ... Equation (2)

Equation (1) is an equation to be satisfied in the bonding step as described above, and Equation (2) is an equation to be satisfied in the bonding step and the prestressing step.

Where p _splice is the bonding pressure acting on the spacer, E _el is the secant modulus of elasticity of the spacer, t _el is the thickness of the spacer, t _error is the maximum normal direction of the joint, and t _epoxy is the epoxy coating thickness. , p _jack is the pressure or compressive stress acting on the spacer by the tension of tendon when prestress is introduced, σ _allow is the allowable compressive stress of the concrete at the joint, and p _splice is the bonding pressure acting on the spacer in the bonding step. As defined by Equation (3) below, p _{jack, which} is the pressure or compressive stress acting on the spacer by tension of the tendon in the prestressing step, is defined by Equation (4) below.

…………………………………………식(3)

... ... ... ... ... ... ... ... ... ... ... ... ... ... ... ... Equation (3)

…………………………………………식(4)

... ... ... ... ... ... ... ... ... ... ... ... ... ... ... ... Formula (4)

Where F _splice is the bonding force acting on the spacer, A _el is the area of the spacer, E _epoxy is the secant modulus of epoxy, and σ _x is the longitudinal compressive stress of the girder acting on the cured epoxy. It is the stress due to the tensile force calculated by the void for the cross section.

Equation (1) is a conditional expression that must be satisfied at the time of joining the segment. That is, the thickness of the spacer 10 compression-deformed by the joining pressure should be smaller than the epoxy 20 coating thickness, but larger than the fabrication error of the joint surface. It means that. Therefore, if Equation (1) is satisfied, the bonding pressure acts only on the part contacting the spacer 10 in the bonding step, and all of the remaining gaps except the spacer 10 between the joint surfaces of the segments to be bonded. Filled with epoxy 20. That is, the epoxy 20 tightly fills the gap between the joining surfaces of the two segments, and the joining surfaces of the segments are adjacent to each other with the spacer 10 therebetween without direct contact. Equation (2) is a conditional expression that restricts the sum of the pressure acting on the spacer 10 during the bonding process and the pressure acting on the spacer 10 during the prestressing step so as not to exceed the allowable stress of the concrete. In this case, it is possible to prevent local failure such as split cracking or spattering due to stress concentration at the joint in all processes. In addition, although not separately expressed in the above equation, the breakage of the spacer 10 during the joining operation should be naturally prevented, and the stress at the site connected with the epoxy 20 should not exceed the allowable stress of the concrete. In addition, in practice, it is preferable to include an appropriate safety factor in Equation (1) and Equation (2).

Σ _x due to tension is a very large stress. As can be seen from Equation (2), if the elastic modulus of the spacer is sufficiently small compared to the cured epoxy elastic modulus, p _jack Is a small value. In addition, since the bonding pressure ( p _splice ) acting on the spacer is proportional to the bonding force ( F _splice ) and inversely proportional to the area ( A _el ) of the spacer, as in Equation (3), the size can be easily calculated. . Therefore, the permissible condition of the part in contact with the spacing member represented by equation (4) can be easily satisfied through simple calculation.

For example, if a segment segment is made of concrete with a compressive strength of 70 MPa, and the joining pressure required for joining the segments is 2 MPa, and the total area of the spacer 10 is 1/10 of the girder cross-sectional area, the gap is maintained in the bonding step. The pressure acting on the ash 10 is 20 MPa. And if the stiffness ratio of the cured epoxy 20 and the spacer 10 is 1/10, when acting up to the allowable concrete stress 42MPa which is the maximum stress that can act on the girder in the prestressing step to act on the spacer 10 The pressure is 4.2 MPa. Therefore, the final pressure acting on the spacer 10 is 24.2 MPa, which is sufficiently smaller than the allowable concrete stress of 42 MPa, thereby enabling safe bonding and prestressing.

However, the above equation is a formula expressed assuming that a uniform pressure acts on all the spacers 10 during bonding. In fact, different deformations and pressures are applied to the spacers due to manufacturing errors and alignment errors. In this case, the relationship between the strain and the working pressure can be calculated through the following stress-strain relationship.

…………………………………………식(5)

... ... ... ... ... ... ... ... ... ... ... ... ... ... ... ... Formula (5)

Where p is the bonding pressure acting on the spacer, ε is the strain, and t is the final thickness after deformation of the spacer. E is the modulus of elasticity of the spacer, which is expressed as a function of strain (ε) because most materials have a nonlinear relationship between stress and strain when the strain is large. Using equation (5), it is possible to calculate the difference in pressure according to the difference in deformation thickness of the spacer.

Considering the selection conditions of the spacing member 10 as described above, rubber may be considered as a material of the spacing member 10. However, rubber generally has a problem that the strain is excessively too small at a stress level acting in the bonding step to less than 1/100 of the hardened epoxy stiffness. However, when the shape factor (= cross-sectional area / circumferential area) is large, that is, when the cross-sectional area is larger than the thickness of the spacer in this embodiment, the rigidity is increased by 10 times or more due to the volume expansion restraint effect that occurs during deformation. Can be obtained. In addition, rubber is one of the materials suitable for use as the gap retainer 10 because rubber is a method of increasing rigidity by reinforcing with fibers or the like.

The above joining method using a flexible spacer is applicable to segmental girder of various cross-sectional shapes. One thing to note is that the joint surface is connected by two different materials, namely epoxy 20 and the spacer 10, the stress transfer process is also different. Of course, it is possible to control not to cause problems through stress calculation, but it is inevitable that the efficiency of the cross section at the joint is somewhat reduced. However, since the optimization of the cross section is determined at the position where the maximum cross-sectional force is applied, the reduction of the cross-sectional efficiency of the joint does not affect the optimization of the girder cross-section if the joint of the segment is made at the position where the maximum cross-sectional force is not applied.

As described above, according to the present invention, the final thickness of the spacer retained by the bonding force is greater than the maximum normal direction error of the joint so that the joint does not come into direct contact with each other, and the spacer retains rigidity sufficiently smaller than that of the epoxy. Local stress cracking by stress concentration by limiting the final compressive stress not to exceed the allowable stress of the concrete by minimizing the increase of the stress of the concrete in contact with the spacer 10 by the tension force acting after the epoxy curing. And it is possible to provide a segmented prestressed concrete box beam and a method of joining thereof, which can prevent partial breakdown of the joint such as dropout. On the other hand, when manufacturing the segment due to this feature, as shown in Fig. 11, the precision separation block (S2) made by precisely processing the shape of the joint surface on both sides of the segment separating plate (S1) of uniform thickness or both. It is also possible to use all the segments of a girder at once by inserting them in the middle of the formwork.

While the above provides specific details for the practice of the present invention by describing the preferred embodiment of the present invention, the technical idea of the present invention is not limited to the described embodiments, and is not intended to be contrary to the technical idea of the present invention. It can be embodied in various forms of segmented prestressed concrete box beams and their joining methods.

S: segment 10: spacing material
20: epoxy 30: expansion joint

Claims (10)

In the method of joining the segmented prestressed concrete box beam,
A spacing member installation step of installing a spacing member of a material having ductile stiffness than the stiffness of the cured epoxy between two joining surfaces of the pair of segments to be joined;
An epoxy coating step of applying epoxy to the joint surfaces of the pair of segments to be bonded in the state where the spacer is installed;
When the gap retaining material is installed and the epoxy is coated, the applied epoxy is squeezed by applying the bonding pressure in the direction in which the segments to be bonded are close to each other. Bonding to form a tight epoxy layer by filling with the epoxy;
An epoxy curing step of curing the epoxy while maintaining the bonding pressure after the bonding step;
A prestressing step of tensioning the tendon by inserting the tendon after the curing of the epoxy is completed; Including,
Exposing some reinforcing bars on top of the junction in the manufacture of said segments,
Pressing some of the reinforcing bars arranged on the upper part of the segments to be bonded in the bonding step in a direction in which the adjacent to each other with a coupler,
After the deformation of the spacer retained by the pressure in the bonding step, the thickness is smaller than the coating thickness of the epoxy but larger than the maximum error in the normal direction of the bonding surface so that a tight epoxy layer is formed between the bonding surfaces and the bonding surface of the segment to be bonded is Do not directly contact, and by using a gap retaining material of a material less rigid than the rigidity of the cured epoxy to lower the pressure applied to the gap retaining material in the prestressing step after curing the epoxy to the gap retaining material in the bonding step and the prestressing step A method of joining a segmented prestressed concrete box beam, characterized in that the sum of the acting pressures is smaller than the allowable compressive stress on the concrete bridge design, concrete structural design, or railway design criteria for the joint.

In the method of joining the segmented prestressed concrete box beam,
A spacing member installation step of installing a spacing member of a material having ductile stiffness than the stiffness of the cured epoxy between two joining surfaces of the pair of segments to be joined;
An epoxy coating step of applying epoxy to the joint surfaces of the pair of segments to be bonded in the state where the spacer is installed;
When the gap retainer is installed and the epoxy is coated, the applied epoxy is squeezed by applying the joining pressure in the direction in which the segments to be joined are close to each other. Bonding to form a tight epoxy layer by filling with the epoxy;
An epoxy curing step of curing the epoxy while maintaining the bonding pressure after the bonding step;
A prestressing step of tensioning the tendon by inserting the tendon after the curing of the epoxy is completed; Including,
Inserting an anchor bolt, part of which is exposed to the upper side of the joint side during the manufacture of the segments,
And further comprising a bonding device for installing a fixing plate fixed to the anchor bolt by the first nut and the both ends are coupled to the fixing plate by a second nut and the rod-shaped computer screw disposed in the longitudinal direction of the box beam ,
Rotate the second nut in the bonding step to press the segments in a direction adjacent to each other,
After the deformation of the spacer retained by the pressure in the bonding step, the thickness is smaller than the coating thickness of the epoxy but larger than the maximum error in the normal direction of the bonding surface so that a tight epoxy layer is formed between the bonding surfaces and the bonding surface of the segment to be bonded is Do not directly contact, and by using a gap retaining material of a material less rigid than the rigidity of the cured epoxy to lower the pressure applied to the gap retaining material in the prestressing step after curing the epoxy to the gap retaining material in the bonding step and the prestressing step A method of joining a segmented prestressed concrete box beam, characterized in that the sum of the acting pressures is smaller than the allowable compressive stress on the concrete bridge design, concrete structural design, or railway design criteria for the joint.
The method according to claim 1 or 2,
An expansion joint construction step of constructing an expansion joint that has a predetermined thickness and an area in each of the portions to be joined and has a predetermined thickness and area, and when the opposite surfaces of the segments are joined, and which is expanded into the box. ; More,
Bonding method of the segmented prestressed concrete box beam, characterized in that for attaching the gap retaining material to the expansion joint in the gap retaining material installation step, and to apply the epoxy to the expansion junction in the epoxy coating step.
The method according to claim 1 or 2,
Bonding method of the segmented prestressed concrete box beam, characterized in that the rubber is used as the spacing retainer having a large area compared to the thickness.
delete For segmented prestressed concrete box beams,
A pair of segmented prestressed concrete boxbeam segments joined together;
It is applied to the joint surface of the pair of segments, and squeezed by the application of the bonding pressure in the direction in which the segments are close to each other in the gel state before curing, the gap excluding the gap retaining material among the gaps between the joint surfaces of the segments. Epoxy cured in a tightly filled state;
The thickness after deformation by the joining pressure is smaller than the coating thickness of the epoxy so as to be attached to any one of the joining surfaces of the pair of segments and not directly contact the joining surfaces of the segments when the joining pressure is applied. Spacing retaining material larger than the normal maximum error of the joining surface of the electrodes;
And a blockout part provided at an upper portion of the joint side of the segments and having a portion of concrete removed therefrom.
Reinforcing bars which can be connected to each other by a coupler are exposed in the block out part.
The spacer is composed of a material having a stiffness than the rigidity of the cured epoxy, and when the prestress is applied to the segments after curing the epoxy to lower the pressure acting on the spacer maintaining the bonding pressure and prestress Segmented prestressed concrete box beam, characterized in that the sum of the pressure acting on the spacer in the process is less than the allowable compressive stress on the concrete bridge design standards, concrete structural design standards or railway design standards for the joints of the segments.
For segmented prestressed concrete box beams,
A pair of segmented prestressed concrete boxbeam segments joined together;
It is applied to the joint surface of the pair of segments, and squeezed by the application of the bonding pressure in the direction in which the segments are close to each other in the gel state before curing, the gap excluding the gap retaining material among the gaps between the joint surfaces of the segments. Epoxy cured in a tightly filled state;
The thickness after deformation by the joining pressure is smaller than the coating thickness of the epoxy so as to be attached to any one of the joining surfaces of the pair of segments and not directly contact the joining surfaces of the segments when the joining pressure is applied. Spacing retaining material larger than the normal maximum error of the joining surface of the electrodes;
Anchor bolts are partially exposed on the upper side of the junction portion of the segments,
A fixing plate fixed to the anchor bolt by a first nut;
Temporary fixing means including a rod-shaped computer screw coupled to the fixed plate provided in the segments adjacent to each other by the second nut, both ends thereof;
The spacer is composed of a material having a stiffness than the rigidity of the cured epoxy, and when the prestress is applied to the segments after curing the epoxy to lower the pressure acting on the spacer maintaining the bonding pressure and prestress Segmented prestressed concrete box beam, characterized in that the sum of the pressure acting on the spacer in the process is less than the allowable compressive stress on the concrete bridge design standards, concrete structural design standards or railway design standards for the joints of the segments.
The method according to claim 6 or 7,
A segmented prestressed concrete box beam having a predetermined thickness and area in each of the segments to which the segments are joined, which may be joined at the same time when the opposite faces of the segments are joined, and an enlarged joint extending into the box.
The method according to claim 6 or 7,
Segmented prestressed concrete box beam, characterized in that the gap retaining material is a large rubber area compared to the thickness.



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