Bridge construction method and bridge

Abstract

Bridge construction method for a bridge formed by a series of beams placed between slabs, supported by angular profiles affixed to the beams. The method includes the steps of: fixing clips to edges of the upper surface of the beams, placing the beams on their supports, calculating the correct position of the angular profiles according to the shape or position of the beams; joining fasteners on the angular profiles, at an individual height determined according to the calculated positions; affixing the fasteners to the clips, so the angular profiles hang at the edges of the beams placing the slab on the angular profiles and casting concrete on the structure. The slabs are supported by angular profiles joined to the upper surface of the beams through a series of threaded protrusion carrying clips in said upper surface. Fasteners are joined to the clips and affixed to the angular profiles.

Claims

1. A bridge construction method, for a bridge formed by a series of beams, between which forms are placed, the forms are supported by angular profiles affixed to the beams, the method comprising the steps of: calculating a correct elevation of each one of the angular profiles according to a shape or a position of the beams; manufacturing the angular profiles with an individual height or an angle determined according to the calculated elevation; affixing the angular profiles to the beam, so that the angular profiles hang at the edges of the beams, wherein each one of the angular profiles are fixed to the beam at a different individual height with regards to an upper surface of the beam; placing the form on the angular profiles to form a structure; casting a concrete on the structure; wherein the beams are placed on supports at any point before the form placing.

2. The bridge construction method according to claim 1, wherein clips are fixed to the beams before the placement on the supports and the angular profiles are joined to the clips.

3. The bridge construction method according to claim 2, wherein the height of the angular profiles is defined by a position of a fastener affixed to the clips.

4. The bridge construction method according to claim 3, wherein the fasteners are affixed to the clips by a threaded nut.

5. The bridge construction method according to claim 2, wherein the beams are concrete beams and the clips are placed when casting the concrete.

6. The bridge construction method according to claim 2, wherein the beams are steel beams and the clips are welded.

7. The bridge construction method according to claim 1, wherein the individual height of each angular profile is calculated by surveying the beam at a precast factory.

8. The bridge construction method according to claim 1, wherein the individual height of each angular profile is calculated once the beam is placed on the supports.

9. The bridge construction method according to claim 1, wherein the angular profiles are affixed to the beams by a bolt fired by a bolt gun.

10. The bridge construction method according to claim 1, wherein the angular profiles are Z profiles and the individual height of the angular profiles is defined by a length of a middle portion.

11. A bridge formed by the method of claim 1, and comprising: at least two beams and a series of forms between adjacent beams, wherein the forms are supported by angular profiles joined to an upper surface of the beams, wherein each one of the angular profiles can be fixed to the beam at a different individual height with regards to a top surface of the beam; thus, the angular profiles are different at each point.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) To complement the description below and in order to provide a better understanding of the invention, a set of drawings is attached as an integral part of said description according to a preferred example of its practical embodiment. In those drawings, with an illustrative and non-limiting nature, the following has been represented:

(2) FIG. 1 shows a front view of an example of a bridge with the forms and the angular profiles, a L profile in this case;

(3) FIG. 2 shows a perspective schematic view of an embodiment of the upper surface of the beam with clips, and a view of the complete clip;

(4) FIG. 3 shows a perspective schematic view of the embodiment of FIG. 2 with the angular profiles and fasteners when the angular profile is welded to the fastener;

(5) FIG. 4 shows a perspective schematic view of another embodiment of the beam with the angular profiles and fasteners when the angular is bolted to the fastener;

(6) FIG. 5 shows a front view of a second example of a bridge with the forms and the angular profiles shaped like a Z;

(7) FIG. 6 shows a perspective schematic view of another embodiment of the beam with the angular profiles; and

(8) FIG. 7 shows a perspective schematic view of a third embodiment of the upper surface of the beam without clips.

DETAILED DESCRIPTION OF THE INVENTION

(9) FIG. 1 shows a schematic of a bridge where the invention is applied. It can be seen that the bridge has a series of beams (1), with a substantially horizontal upper surface (11) from which some reinforcement bars (12) usually protrude. Between two adjacent beams (1) there is a form (2) supported by both beams (1). The form (2) is usually made of metal, as in precast metal deck (PMD) or steel in place (SIP) manufacturing methods, but other materials can be used. For instance, concrete can be also used. The support of the form (2) on each beam (1) is carried out by separate longitudinal angular profiles (3) of steel plate. These angular profiles (3) are welded to a set of fasteners (5) at the right height. Then the fasteners (5) are supported by the threated studs (41) welded to the clips (4) embedded in the concrete beam (1). In case of a steel beam, the clips (4) may only contain the threated studs (41), directly welded on top of the steel beam (1).

(10) FIG. 2 shows another perspective of the beam (1). It comprises a set of clips (4) embedded or fixed to its upper surface (11), close to the edge. The clips (4) have a threaded protrusion (41) perpendicular to the upper surface (11). Those threaded studs (41) are set at a predetermined distance, e.g., one each 1-4 feet. The clips (4) can be placed when casting the concrete beam or welded to the metal beam in the factory. Therefore, the beam (1) carries the clips (4) before its placement in the manufacturing phase. In FIG. 2 an exemplary embodiment of the clip (4) is shown. The clip has an insertable part (42) so the concrete can better take hold the clip (4). The insertable part (42) may have a hole for a rebar or for the concrete to grip the clip (4).

(11) The angular profiles (3) are disposed at the side of the beam (1), as shown in FIGS. 1, 3 and 4. They are fixed to the clips (4) through several fasteners (5). FIGS. 3 and 4 show two different examples of fasteners (5). The fasteners (5) may have a slotted hole for each threaded protrusion (41) so it adapts to small placing errors. The fasteners (5) are held in place by nuts, washers or the like, threaded in the threaded protrusions studs (41). FIG. 3 show the fasteners (5) welded to the profiles (3) at the right elevation or height. FIG. 4 shows the fasteners (5) attached to the angular profiles (3) through a second threaded stud with nuts and washers, in this case the right elevation is achieved through a slotted profile in the vertical part of the angular profile (3).

(12) In order to ensure the correct placement of the form (2), each fastener (5) is joined to the angular profiles (3) at different heights (see FIG. 3). Therefore, even if the beam (1) is not at its exact position or is cambered, the form (2) rests on angular profiles (3) at the right elevation.

(13) As specially seen in FIG. 3, the height of the angular profile (3) at each point is different, so each fastener (5) is welded at a different point. Therefore, the angular profile (3) is shown with an angle, i.e., not parallel to the upper surface (11) of the beam (1). This effect is embellished in the figure to better show the intermediate result of the method.

(14) FIG. 5 shows a schematic of another bridge where the invention is applied. Most of the elements are the same as in FIG. 1. However, in this case, the angular profiles (3) are Z profiles, as in FIG. 6. Z profiles don't require a fastener, the profile is held by the clips (4) on its own. The support of the form (2) on each beam (1) is carried out by separate longitudinal Z profiles of steel plate. This Z profiles are supported by the threated studs (41) welded to the clips (4) embedded in the concrete beam (1). In this embodiment, the vertical part of the Z profile is variable in order to adjust the elevation of the form (2).

(15) FIG. 6 shows another perspective of the beam (1). It comprises a set of clips (4) embedded or fixed to its upper surface (11), close to the edge. The clips (4) have a threaded protrusion (41) perpendicular to the upper surface (11). Those threaded studs (41) are set at a predetermined distance, e.g., one each 1-4 feet. The clips (4) can be placed when casting the concrete beam or welded to the metal beam in the factory. Therefore, the beam (1) carries the clips (4) before its placement in the manufacturing phase.

(16) The Z profiles are disposed at the side of the beam (1), as shown in FIGS. 5 and 6. They are fixed to the clips (4) through the top part of the Z profiles. The top part of the Z profiles may have a slotted hole for each threaded protrusion (41) so it adapts to small placing errors. The Z profiles are held in place by nuts, washers, or the like, threaded in the threaded studs (41).

(17) The adjustment can be calculated by surveying the beam at the precast factory, so any error is measured and can be corrected. It can also be measured on site. In this case, once the beam (1) is placed on the columns, the position of the beam (1) is determined. A GPS, a system of radio beacons, a survey prism on the robot in combination with a total station for providing coordinates or any other high-precision system, as a 3D survey scanner to have the real elevation of the beam (1) can be used. This elevation is compared to the theoretical position of the beam (1) or the form (2). For example, using a BIM (Building Information Modeling) database can be used to find out the theoretical position of the beam (1) or the from (2) in the bridge manufacturing plans, or any other model may be used to calculate the theoretical position.

(18) This knowledge allows to determine the distance between the edge of the beam (1) and the theoretical position of the form (2). Therefore, the distance between the edge of the beam (1) and the angular profile (3) can be defined at each point of the beam (1). Once those distances are calculated, the fasteners (5) can be joined to the angular profiles (3) at the right position or height. This way, the forms (2) are placed at exactly the right position, and so are the angular profiles (3) at each side (see FIG. 1).

(19) The third alternative (FIG. 5) the distance between the edge of the beam (1) and the support of the Z profile can be defined at each point of the beam (1). Once those distances are calculated, the Z profile are bended to the right elevation or height. This way, the forms (2) are placed at exactly the right position, and the Z profiles at each side (see FIG. 1).

(20) As shown in the figures, the fastener (5) can be joined to the L profiles in several ways. They can be welded together, joined by a nut and bolt, adhered to each other . . . . The only two requisites are the exactitude of the placement and the mechanical resistance. In FIG. 4C, the fastener (5) carries a bolt that passes through a slot in the L profile so as to allow for the variation of position. When the nut is tightened, the height is defined.

(21) The fasteners (5) are joined to the L profiles on the ground, so the workers can do their tasks safely. Once joined, they can be placed on the clips (4) and fixed with a nut and bolt. This manipulation on site is fast and can be done with powered tools, so the time spent on top of the beam (1) is greatly reduced. In a similar way, the Z profiles will be made on the ground, so the operations on top of the beam (1) are also reduced. The need to be on top of the beam can be eliminated if the angular profiles (3) are attached to the beams (1) even before erecting the beams (1). In this manner we reduce the risk of the worker to the minimum.

(22) In FIG. 7, still another embodiment is shown. In this case, the angular profile (3) is attached to the beam through a bolt (6). This way, the clip (4) is not necessary. The bolt (6) can be inserted in the concrete beam (1) with the aid of a concrete bolt gun. The angular profile (3) will be already pierced to reduce the resistance to the bolt (6).