KR100847724B1 - Method for a prestressed concrete pavement into the transverse direction of road - Google Patents

Abstract

A transverse prestressed concrete pavement method of a road is provided to make construction simple by prestressing a concrete pavement of a general road in the transverse direction, and installing a first tendon and placing concrete per each lane and connecting with a second tendon of the next lane using a coupler, and to extend the service life of a concrete pavement and to exclude the necessity of maintenance work by preventing the formation of cracks and preventing a vertical joint from being damaged and widened. A transverse prestressed concrete pavement method of a road comprises the steps of: installing a first tendon(20a) in a part for concrete pavement to construct a concrete slab(10a) to one lane of a road; paving concrete to a part for concrete pavement; installing a second tendon(20b) to a part for concrete pavement in the transverse direction to construct a concrete slab(10b) to the next lane, and connecting one end of the second tendon and the one end of the first tendon using a coupler(40); and placing concrete to a part for concrete pavement.

Description

Method for a prestressed concrete pavement into the transverse direction of road}

The present invention relates to a lateral prestressed concrete pavement method of the road, and more particularly, to introduce the prestress in the lateral direction to the concrete pavement of the general road, and after finishing the first tendon and concrete for one lane The construction is easy because the second tendons are connected to the first tendons using the coupler when constructing the second lane and the concrete for the next lane, thereby connecting the tendons installed transversely in each lane of the road. Of course, the transverse prestress of the road can suppress the occurrence of cracks, prevent breakage and joint gaps in the joint, thereby extending the life of the concrete pavement and providing high quality concrete pavement without maintenance. It relates to a concrete paving method.

Prestressed concrete structure, as is well known, refers to a concrete structure that is pre-tensioned by the tendon to resist the load on the concrete structure.

In general, the girder 1 of the bridge is formed of such prestressed concrete, and as shown in FIG. 1 for applying prestress, a duct 2 for receiving the tendon 3 and the tendon 3, and the tendon A fixing device 4 or the like for fixing (3) to the girder 1 is used.

At this time, the fixing unit 4 is installed at both ends of the girder 1, the tendon 3 is fixed to the fixing unit 4 after tensioning one end of the tendon 3 with a hydraulic jack or the like.

On the other hand, the tendon 3 is usually composed of a plurality of strands.

In addition, the tension of the tendon 3 may be tensioned once during the construction of the girder 1, or may be tensioned during the use of the bridge after the construction is completed.

As such, in the bridge, a method of reinforcing the concrete structure by the tension force of the tendons 3 by introducing prestress into a concrete structure such as the girder 1 is widely used.

In addition, the jointed concrete pavement (JCP) is mostly used in general concrete roads that are not bridges. That is, in a general concrete road, the concrete slab is constructed by installing concrete after installing the dowel bar, and a transverse joint (joint) is formed at a predetermined distance of the concrete slab. At this time, the concrete laying can not be laid at the same time the entire lane of the road at the same time is usually laid one lane, when constructing another lane longitudinal joints (joints) are formed between each lane.

However, general roads with conventional joint concrete pavement are applied due to volume change due to shrinkage of concrete, curling caused by temperature difference between upper and lower slabs, warping caused by humidity difference, and friction between slab and lower substrate. Many cracks occur due to constrained stress and stress caused by loads, resulting in shorter pavement life, and huge budgets are being spent on maintenance and repair of concrete pavement. And the delay has a problem that adds to the inconvenience of the user.

Therefore, in the case of a general road using a concrete pavement method, it is urgent to develop a method that prevents breakage at the joint (joint) and requires no maintenance.

An object of the present invention for solving the above-described conventional problems is to introduce prestress in the transverse direction to the concrete pavement of a general road, as well as the first tendon for one lane and the second tendon for the next lane after the concrete laying is finished. And construction by connecting the second tendon to the first tendon by using a coupler when constructing concrete, thereby connecting the tendons installed transversely in each lane of the road, making construction simple and suppressing the occurrence of cracks. Provides a transverse prestressed concrete pavement method for roadways that prevents breakage and joint flaking in the longitudinal joints, thereby extending the life of the concrete pavement and providing high quality concrete pavement without maintenance It is.

The present invention for achieving the above object, the first tendon installation step of installing the first tendon in the transverse direction of the site where the concrete will be installed to install the concrete slab 10 in one lane of the road, After the installation of one tendon, the first concrete laying step of laying concrete at the site where the concrete is to be laid, and after the concrete laying for the one lane is finished, the concrete is to be laid to construct the concrete slab in the next lane. After installing the second tendon in the transverse direction of the site, the second tendon installation step of connecting one end of the second tendon and one end of the first tendon with a coupler, and after installing the second tendon, the concrete Characterized in that it comprises a second concrete laying step of laying concrete on the site to be laid.

In the present invention, when the pre-stress is introduced to the concrete pavement of the general road in the lateral direction, and the concrete laying on one lane is finished, and the concrete pavement is connected to the next lane, the second tendon is removed using a coupler. Construction by connecting one tendon while connecting the tendons installed transversely in each lane of the road, making construction easier, as well as suppressing the occurrence of cracks, breakage and joint opening in joints This can extend the life of concrete pavement and provide high quality concrete pavement without maintenance.

In addition, it is possible to integrate the tendons installed in each lane of the road through the coupler and at the same time to introduce the prestress in the transverse direction to all lanes, thereby further improving the effect of preventing the occurrence of cracks on the road and further extend the life.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

Repeated description of the same parts as in the prior art will be omitted.

2 is a plan view showing a case in which one lane is constructed in the lateral prestressed concrete pavement method of the road according to the present invention, FIG. Is a plan view showing a case in which two lanes are constructed in the lateral prestressed concrete pavement method of FIG. 5, FIG. 5 is a sectional view showing the BB line in FIG. 4, and FIG. 6 is a lateral prestressed concrete pavement method of the road according to the present invention. It is a block diagram showing.

Prior to the description, the road is usually composed of a multi-layer pavement layer, for example, from the lower layer to an auxiliary base layer (not shown), base layer (not shown), concrete pavement (concrete slab 10a, 10b) Of course, the pavement layer of the structure may be variously changed according to the road environment.

The concrete slabs 10a and 10b are formed through concrete laying on the uppermost surface of the pavement layer of the road.

Since the concrete slab (10a, 10b) is repeated expansion and contraction by the difference in temperature, humidity, joints (joints) are formed at regular intervals to reduce the stress caused by this and to suppress the occurrence of cracks.

Here, the joint (joint) is a horizontal joint (joint) formed in the transverse direction (the width direction of the road) of the concrete slab (10a, 10b), and a longitudinal joint (joint) formed in the longitudinal direction (the longitudinal direction of the road); Not shown).

On the other hand, the concrete slab (10a, 10b) is usually constructed by one lane.

And, the transverse prestressed concrete pavement method of the road according to the invention, the first tendon installation step (S1), the first concrete installation step (S2), the second tendon installation step (S3), and the second concrete The installation step (S4) is made.

First, the position display step may be performed before the first tendon installation step S1. The position display step is a step of displaying the installation position of the first tendon 20a in advance in the site where the concrete will be laid in order to construct the concrete slab 10a on the road.

That is, the installation of the first tendon 20a can be simplified by displaying the installation position and the interval of the first tendon 20a in advance.

In addition, a spacer (not shown) is installed at an installation position of the first tendon 20a. The spacer is adjusted to the installation height of the first tendon 20a to be located in the middle or lower portion of the vertical direction of the concrete slab 10a.

In addition, in the position display step, the installation position of the tendon 30 is installed in the longitudinal direction of the road.

end. First tendon installation step (S1)

The first tendon installing step (S1) is a step of installing the first tendon 20a in the transverse direction of the site where the concrete will be laid in order to construct the concrete slab 10a in one lane of the road.

That is, since the installation position of the first tendon 20a is marked in advance in the position display step, the first tendon 20a can be easily installed.

Here, when the first tendon 20a ends with one lane, as shown in FIG. 2, a PS steel wire, a PS stranded wire, or a PS steel bar may be used, and the first lane 20a is extended by two or more lanes. It is preferable to use a PS steel bar.

Here, when the first tendon 20a is composed of PS steel wire or PS steel wire, several strands are used.

And, in the first tendon installation step (S1), as shown in Figure 3, the duct 21 coupled to the pressure plate (22, 25) at both ends is installed outside the first tendon (20a), the first One end of the one tendon 20a is fixed with a nut 23 in an outer direction of the one side pressure plate 22, and the other end thereof has a nut inside the tension pocket 27 provided in an outer direction of the other side pressure plate 25. 26).

That is, the pressure plate 22, 25 coupled to both ends of the duct 21 is installed to be located on both sides of the transverse direction of the site where the concrete is to be placed, the first tendon 20a is the duct 21 In the state of being inserted into the both ends thereof penetrates the pressure plate 22, 25 coupled to both ends of the duct 21.

At this time, one end of the first tendon 20a is fixed with a nut 23 in the outward direction of one side pressure plate 22 of the duct 21, and the other end is the other side pressure plate 22 of the duct 21. It is fixed by the nut 26 in the inside of the tension pocket (27) installed in the outward direction.

Here, the support plate 27a for supporting the nut 26 is formed in the tension pocket 27.

As such, since the first tendon 20a needs to be tensioned after the concrete is cured later, one end portion is configured to be fixed to one end portion of the concrete slab 10a, and the other end portion is provided through a tension pocket 27. It consists of a structure that can be tensioned.

On the other hand, when the first tendon 20a is made of a PS steel bar, one end of the first tendon 20a may be fixed with a nut 26 in the tension pocket 27, and the first tendon 20a may be used. ) Is made of PS steel wire or PS steel wire, one end of the first tendon 20a may be fixed by using a wedge (wedge) (not shown) inside the tension pocket 27. Here, the method of combining tendons using the wedge is well known, and thus detailed description thereof will be omitted.

In addition, a grouting injection pipe 21a is installed at one side of the duct 21 to grout the inside of the duct 21 after the tension of the first tendon 20a is completed. In this case, the grouting injection pipe One end of the 21a is installed in communication with the outside of the concrete slab 10a.

In the first tendon installation step S1, the longitudinal tendon 30 is installed in a direction orthogonal to the first tendon 20a above the first tendon 20a installed in the transverse direction of the road. The longitudinal tendon 30 is also installed in the same manner as the installation structure of the first tendon 20a, in which case the longitudinal tendon 30 is composed of a PS steel wire or a PS stranded wire because of its long length.

In addition, the fixing unit 31 coupled to both ends of the longitudinal tendon 30 is installed at both ends in the longitudinal direction at the site where the concrete will be placed.

In addition, in the first tendon installation step S1, reinforcing bars (not shown) may be further installed to reinforce the strength of the concrete slab 10a.

The first tendons 20a installed in the lateral direction of the road are spaced apart from each other by a predetermined interval in the longitudinal direction of the road.

I. First concrete laying step (S2)

The first concrete installation step (S2), after installing the first tendon (20a), is a step of laying concrete in the site where the concrete will be installed.

Then, when the concrete is cured, one end of the first tendon 20a is fixed in a state of being embedded at one end in the transverse direction of the concrete slab 10a, and the other end is the other end in the horizontal direction of the concrete slab 10a. It is located inside the tension pocket 27 installed in the fixed with a nut (26).

In addition, even when the concrete is cured, the first tendon 20a may be located inside the duct 21, thereby allowing the first tendon 20a to be tensioned.

Then, after curing of the concrete laid in the first concrete installation step (S2), the first tendon tension step for tensioning the first tendon 20a is performed. That is, after tensioning the first tendon 20a with a hydraulic jack in the tension pocket 27, the first tendon 20a is tensioned by tightening the nut 26.

Here, the tension of the first tendon 20a may be pulled out at once, but may also be tensioned twice at regular intervals.

In addition, after the tension of the first tendon 20a is completed, a grouting step of performing grouting with concrete inside the duct 21 installed to surround the outside of the first tendon 20a is performed. That is, grouting is performed through the grouting injection pipe 21a installed at one side of the duct 21.

On the other hand, tendon 30 provided in the longitudinal direction of the road is also tensioned by the above method. In the case of longitudinal tendon 30, since it is made of PS steel wire or PS steel wire can be tensioned by a separate hydraulic jack.

All. Second tendon installation step (S3)

The second tendon installation step (S3), after finishing laying the concrete for the one lane, the second tendon (20b) in the transverse direction of the site where the concrete will be laid in order to construct the concrete slab (10b) in the next lane To install, but one end of the second tendon 20b and one end of the first tendon (20a) is a step of installing the coupler 40.

In the second tendon installation step (S3), as shown in FIG. 5, a duct 21 having a pressure plate 25 coupled to one end thereof is installed outside the second tendon 20b and the second tendon 20b. One end of the) is fixed to one end of the first tendon (20a) through the coupler 40, the other end of the nut 26 in the tension pocket 27 provided in the outward direction of the pressure plate 25 Is fixed.

Here, the pressure plate 22 and the nut 23 are omitted in the portion where the coupler 40 is coupled in the second tendon 20b, and the duct 21 surrounds the outside of the second tendon 20b. While being installed to extend to the portion where the coupler 40 is installed.

In addition, the coupler 40 is formed in the shape of a circular pipe, and a tab is formed therein to screw the opposite ends of the first and second tendons 20a and 20b. Of course, the coupler 40 may be formed in various structures.

As described above, in the second tendon installing step S3, the first tendon installing step described above is performed except that one end of the second tendon 20b is connected to one end of the first tendon 20a by the coupler 40. Since it is the same as S1), detailed description is omitted.

On the other hand, the second tendon 20b is formed of a PS steel bar because it must be constructed while connecting the first tendon 20a and the coupler 40.

la. Second concrete laying step (S4)

The second concrete laying step (S4), after installing the second tendon 20b, is a step of laying concrete at the site where the concrete will be placed.

When the concrete is cured, one end of the second tendon 20b is connected to the first tendon 20a through the coupler 40 at one end in the lateral direction of the concrete slab 10b, and the other The end is located inside the tension pocket 27 installed at the other end of the concrete slab 10b in the transverse direction and fixed with a nut 26.

In addition, even when the concrete is cured, since the second tendon 20b is located inside the duct 21, the second tendon 20b may be tensioned.

Then, after curing of the concrete laid in the second concrete laying step (S4), the second tendon tension step for tensioning the second tendon 20b is performed. That is, the second tendon 20b may be tensioned by rotating the nut 26 coupled to the end of the second tendon 20b in the tension pocket 27.

In this case, the second tendon 20b may be pulled out at a time, but may be tensioned twice at regular time intervals.

In addition, after the tension of the second tendon 20b is completed, a grouting step of performing grouting with concrete inside the duct 21 installed to surround the outside of the second tendon 20b is performed. That is, grouting is performed through the grouting injection pipe 21a installed at one side of the duct 21.

As described above, in the present invention, when the pre-stress is introduced to the concrete pavement of a general road and concrete laying for one lane is completed, and the concrete is connected to the next lane, the coupler 40 Construction by connecting the second tendon 20b to the first tendon 20a by using) to connect tendons 20a and 20b which are installed in each lane of the road in a transverse direction. As a result, construction is simple, as well as suppressing the occurrence of cracks, preventing breakage and joint opening in the joint (joint), thereby extending the life of concrete road pavement and providing high-quality concrete pavement without maintenance.

In addition, the present invention integrates the tendons (20a, 20b) installed in each lane of the road through the coupler 40 and at the same time can be introduced into the pre-stress in all lanes, thereby preventing cracks and breakage of the road This can further extend the service life.

If the tendons 20a and 20b installed laterally in each lane of the road are not integrally connected to each other, breakage and joint opening may occur between the lanes, that is, the joints. .

In the drawings, the first and second tendons 20a and 20b of the two lanes are connected to the coupler 40 to introduce prestresses. However, two or more lanes are also possible.

On the other hand, the lateral prestressed concrete pavement method of the road according to the present invention, as well as general roads and highways, airport pavement (halfway), harbor aprons, railway freight facilities or factories, parking lots, temporary roads (roads), intersections It can be applied to exhibition facilities, surrounding roads, etc.

1 is a cross-sectional view showing a girder of a bridge to which a conventional prestressed concrete is applied,

2 is a plan view showing a case in which one lane is constructed in the lateral prestressed concrete pavement method of the road according to the present invention;

3 is a cross-sectional view showing a line A-A in FIG.

4 is a plan view showing a case in which two lanes are constructed in the lateral prestressed concrete pavement method of the road according to the present invention;

5 is a cross-sectional view showing a line B-B in FIG. 4,

Figure 6 is a block diagram showing a transverse prestressed concrete pavement method of the road according to the present invention.

<Explanation of symbols for the main parts of the drawings>

10a, 10b: concrete slab 20a: first tendon

20b: second tendon 21: duct

22,25: Acupressure plate 23,26: Nut

27: tension pocket 30: longitudinal tendon

40: coupler

Claims (5)

A first tendon installation step S1 of installing a first tendon 20a in a transverse direction of a site where concrete is to be installed in order to construct a concrete slab 10a in one lane of the road; After installing the first tendon (20a), the first concrete installation step (S2) for placing concrete in the site where the concrete will be installed, and After the concrete laying on the one lane is finished, in order to construct the concrete slab 10b in the next lane, the second tendon 20b is installed in the transverse direction of the site where the concrete is to be laid, but the second tendon 20b A second tendon installing step (S3) of connecting one end of the first tendon and one end of the first tendon 20 a to the coupler 40, and After installing the second tendon (20b), the horizontal prestressed concrete pavement method characterized in that it comprises a second concrete laying step (S4) for laying concrete at the site to be laid concrete. The method of claim 1, After curing of the concrete laid in the first concrete laying step (S2), the first tendon tension step for tensioning the first tendon (20a) proceeds, and the concrete laid in the second concrete laying step (S4) After curing, the transverse prestressed concrete pavement method of the road, characterized in that for proceeding the second tendon tension step of tensioning the second tendon (20b). The method of claim 1, The first and second tendons (20a) (20b) is a transverse prestressed concrete pavement method of the road, characterized in that made of PS steel bar. The method of claim 1, In the first tendon installation step S1, the duct 21 coupled with the pressure plate 22 and 25 at both ends is installed outside the first tendon 20a, and one end of the first tendon 20a is provided. The part is fixed with a nut 23 in the outer direction of the one side pressure plate 22, the other end is fixed with a nut 26 in the tension pocket 27 provided in the outer direction of the other side pressure plate (25) Lateral prestressed concrete pavement method of road to use. The method of claim 1, In the second tendon installation step (S3), a duct 21 having the pressure plate 25 coupled to one end thereof is installed outside the second tendon 20b, and one end of the second tendon 20b is formed. It is fixed to one end of the first tendon 20a through the coupler 40, the other end is fixed with a nut 26 in the tension pocket 27 installed in the outward direction of the pressure plate 25 Lateral prestressed concrete pavement method of road to use.

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