HU194591B - Portal supporting structure - Google Patents

Abstract

The ports of the invention are a support structure, e.g. for the placement of signs containing road information, provided with a bridging beam for positioning the information and columns supporting the ends of the bridging beam, the bridging beam is a split profile, preferably a Vierendeel holder. Preferably, the beam has a wedge-shaped cross-section with closed belts and straps that engage the belts, and is provided with a cross-linkage that enhances its spatial stiffness at least near its ends. It is characteristic that the connection between the split-girder, preferably the Vierendel-structured bridging beam (4) and the supporting column (3), is suspended by the hanging members (7) between the upper belts (41) of the bridging beam (4), the supporting column (3) and at least one of the suspension members (7), comprising a steplessly adjustable adjustable support member (14) inserted between the lower belt (42) and the supporting column (3). (Characteristic of Figure 1.) International Class Marking: (51) Int. C1.4: E 04 C 3/04 3/40 Patent: (73) Capital City Planning Company, Budapest -1-

Description

The invention provides a portal support structure, e.g. a road information sign having a bridging beam and columns supporting the bridging beam near its ends. The bridging beam has a split section, preferably a Vierendeel support, preferably having a cross-sectional closed belt and a strap that connects the belts, and is provided with a cross-linking at least near its ends to increase its stiffness.

According to the practice so far, the supporting columns and the most often truss beams attached to them are placed together and fixed permanently in the base body. When setting up a structure in a naturally lying position, the support legs will inevitably rest on the ground, so that the structure may be subjected to stresses that do not occur in the final state. Therefore, it is necessary to resize the connections and some structural elements. The support legs are permanently fixed by concreting them. The structure exposed to the wind load shall be temporarily supported until the concrete has solidified. As the entire surface of the structure can be attacked by the wind, temporary supports should be scaled to the maximum loads of the final structure, which causes a small additional cost.

In practice, the on-site screw assembly of the support column and bridging beam also occurs. The receiving elements are provided with oval holes for the screws to enable the column assembly and the bolt assembly. manufacturing inaccuracies may subsequently be corrected. Due to the nature of the connection, only a very small degree of inaccuracy can be allowed, so high level geodetic measurements are required for column adjustment. This adds up to 5-10 times the column adjustment time. The precise adjustment of the tops of the 6 ni tall columns results in the location of a cart or crane, which increases costs. It is also possible to shorten the work by drilling the holes on site, but this requires bringing a power source to the site. This solution by no means satisfies the requirements of toolless, fast on-site assembly.

U.S. Patent No. 2,341,089 discloses a two-legged bracket with a rectangular cross-section reinforced with a tensioner. The beam rests on the base plate at the top of the column and is screwed down. The relationship has virtually no adjustability, is very sensitive to dimensionality, so it does not meet the intended purpose at all.

Hungarian Patent No. 162,500 discloses a hinged junction connection for joining elements of rod structures. In the embodiment described, three interlocking rod ends are fastened to each other by means of three 120 ° angle screws. The relationship is very sensitive to size tolerance, which is intended to be eliminated by producing the same template. The bonding force is not clean, so overloaded bolts will flow as the wrist develops, and while the structure remains rigid, the connection will become insoluble, thus preventing any renovation work. The solution is inadequate to provide a reliable connection between a beam and a column, despite the large inaccuracies, simply without the need for special equipment. If the beam and column are set independently, the column can only be adjusted with high level geodetic measurements. Thus, the solution of the solution to the set i live does not correspond.

U.S. Patent No. 3,793,790; you know the adjustable elbow bar frame structure. The upper belt of the lattice support is secured to the top of the pillar by means of a plate-plate screw connection, the lower belt is attached to the pillar by means of an elbow. \ There is no dimension tolerance at the connection between the upper belt and the column, and the elbow bar has discrete values, so it can be adjusted. The connection secures the beam to the column in a manner that also provides a torque. The solution icin corresponds to the object of the invention. Λ upper belt 's pillar connection is not adjustable and lower belt and pillar connection can only be adjusted in coarse steps and in one direction.

It is an object of the present invention to provide a connection between a support pillar and a bridging beam that allows for an adjustment far beyond the average for a steel structure in construction. In addition, the connection should only require mechanic work without the need for special equipment. It is a further object of the present invention that the positioning of the column and the positioning of the span beam can be performed independently of one another. In order to minimize the size of the column and the base, and to position the support structure on existing weaker columns, we have aimed to provide a spatially articulated joint with pure power play. Because of the ease of dissolution of the connection, it is a requirement that the elements of the connection remain intact during use and do not suffer any permanent deformation.

The idea of the invention is based on the realization that the construction failure can be divided into three perpendicular components, as well as the reaction forces in the wrist. For other reasons, the ends of the bridging beam having a spatial structure are made infinitely rigid, so that the connection with the column can be arranged on different levels and in different planes without any static disadvantages. Some connections are sensitive only to one-way placement and the other two to two-way placement. The support direction coincides with the positioning sensitivity. Obviously, the construction of a substantially axial structure may be simpler than connections allowing an adjustment of 5 to 10 cm for spatial stresses.

In accordance with the object, the portal support according to the invention is e.g. for providing road information boards having a bridging beam and columns supporting the bridging beam near the ends of the bridging beam, the bridging beam has a split gauge, preferably having a closure cross sectional closure and at least a degree of webbing connecting the belts, and provided - arranged in such a way that the link between the split girder, preferably of the Vierendeel structure, and the support column is suspended from the upper members (41) of the brace beam (4), the support member 23;

It consists of an infinitely adjustable adjustable support member inserted between at least one of the steals and the suspension members, and between the lower belt and the support post.

A further feature of the portal support according to the invention is that the bridging beam has two upper belts and two lower belts, the upper belts being connected to each other and the lower belts to each other by a horizontal strap, and the above belts by a vertical strap.

Near the upper end of the support column, a saruel element is attached, and the sarucicin is optionally supported by stiffening ribs from below. The hanging member is reinforced by means of couplings connecting to the shank. The coupling element comprises an upper beam, a lower beam and an adjustable coupling member, the upper beam and the lower beam encircling the shank member by tensioning the coupling member.

In one embodiment of the device, the lower belts of the rectangular cross-member beam are suspended from the upper belts by inserting a connecting rod near the support column.

In a further embodiment of the supporting structure, the bridging beam has two upper belts and a lower belt, and the upper belts and the lower belt are connected by an oblique strap. At the upper end of the support pillar, a receiving unit, e.g. a frame is secured, and an adjustable support member is inserted between the posts of the frame and the lower belt.

The adjustable support is tensioned against the support pillar or the stool mounted on the lower belts or the support pillar .;

The adjustable support member is attached to the support post or suspension member by means of a bracket and its ends are attached to a stool mounted on the suspension member or support post.

I

The main advantage of the device according to the invention is that it is easy to assemble with simple, quick installation. it is possible to establish a truly reliable relationship. With the connection between the column and the bridging beam, the conditions of the static frame are maximally satisfied; masturbation conditions can be created. Material savings can be achieved by avoiding the extra demand during the lifting process. The setting time can also be significantly reduced. The application of the structure allows the bridging beam to be used in existing, e.g. mounted on a street lighting column. This may result in the cost of the column and foundation not being met.

The invention will now be described in more detail with reference to an example. The attached drawing shows

Figure 1 is a side view of the portal support structure, a

Figure 2 is a cross-sectional view of the bridging beam, a

Figure 3 is a cross-sectional view of the support column and the bridge beam connection, a

Figure 4 is the same top view, of

Figure 5 is the same in longitudinal section, a

Figure 6 is a plan view of the relationship between the column and the lower belts, a

Figure 7 is a possible cross-sectional version of the bridge beam, a

Figure 8 is a search for the relationship between the triangular cross-linking gene and the support column. tmcíszc you.

Figure 1 shows the spatial position of the assembled portal support structure. The concrete columns built into the soil 1 have the support columns 3 <a. The bridging beam 4 rests on the support columns 3. The drawing also shows some of the main structural elements of the 4 bridges: the upper belt 41, the lower belt 42, and the vertical straps 44. In the vicinity of the support pillars 3, reinforcing plates 11 can also be discovered at the ends of the bridging beam 4.

Figure 2 shows the most important components of the bridging beam 4. The upper belts 41 having a closed cupboard cross-section are interconnected by a horizontal strap 43. The upper belts 41 are joined by the lower belts 42 by the vertical strap 44.

Figure 3 is a cross-sectional view showing the reinforcement of the bridging beam 4 around the column 3. The spatial stiffness of the bridging beam 4 is increased by all reinforcing plates and cross-links 9. The lower belts 42 are fastened to the upper belts 41 by the connecting rods 10. It can be clearly seen that the bridging beam 4 is supported by a bracket 5 mounted on the support column 3 by means of a support member 7. The lug 5 is surrounded by the upper rod 81 and the lower rod 82 of the coupling elements 8 by tensioning the coupling member 83. In the plane perpendicular to the direction of the bridging beam 4, the lower belts 42 are supported by the support member 14 on the column 3. The column 3 is in this case welded to the brackets 2 and the lower belt 42 to the stools 13.

Fig. 4 is a top view showing that the suspension members 7 preferably encircle the support column 3. In this way, it is possible to connect 4 bridges to existing columns. When placed, the coupling pieces 8 are pulled next to the upper belts 41, so that the lower beam 82 does not rest on the lug 5. In the final state, the coupling pieces 8 are pulled onto the shank 5 and the shank 5 is clamped by the shunt member 83 with the upper beams 81 and the lower beams 82, as shown in Fig. 5.

Fig. 5 further shows how the crosslinks 9 for stiffening avoid the load bearing connections between the support column and the bridging beam 4. The direction of the connecting rod 10 is clearly visible to apply tensile force in the lower belt 42 to the supported upper belt 41. The forces in the axis of the bridging beam 4 are absorbed by the support member 14 inserted between the suspension member 7 and the support column 3. The details in the figure are only schematically shown, the application of the relationship shown in figure 6 being applied accordingly.

Figure 6 illustrates the position of the support column 3 relative to one another with respect to the brackets 12 attached thereto. The support member 14, in this case the nut securing the nut, rests on the seat 13 to prevent the corrosion protection of the main load-bearing element, the lower belt 42, from being damaged.

Fig. 7 shows the main components of a bridging beam 4 with a triangular cross-section. The upper belts 42 are connected to each other by the horizontal strap 43 and the lower belts 42 by the inclined straps 45.

In Fig. 8, the triangular bridge 4 is a cross-section

194 591 joints between beam and 3 support columns. The frame 15 is fixed at the top of the bridging column 3. The lower frame beam 151 may also be supported by 6 reinforcing ribs. Frame posts 152 surround the upper belts 41, but allow a high degree of insecurity. The support member 14 extending from the brackets 12 welded to the concrete columns 152 rests on the stools 13 mounted on the lower belt 42.

The invention can advantageously be used as a support structure for road information signs in cities, highways and highways outside cities. It can be equipped with traffic lights eg. at the intersections of wide roads over each lane.

Claims (9)

Claims 1. Portal support structure, eg. for placing road signboards having a bridging beam and columns supporting the bridging beam near the ends of the bridging beam, the bridging beam has a split gauge, preferably a Viercndeel, the girder preferably has a secured end piece and at least a secured end; is provided with a cross-link for increasing spatial stiffness, characterized in that the split girder beam (4) of split section, preferably of Vierendeel structure, connects the support member (7) between the upper straps (41) of the girder beam (3). ), consist of an infinitely adjustable adjustable support member (14) inserted between at least one of the support post (3) and the suspension members (7) and between the lower belt (42) and the support post (3). Portal support according to claim 1, characterized in that the bridging beam (4) has two upper belts (41) and two lower belts (42), the upper belts (41) with each other and the lower belts (42) with each other. a horizontal strap (43) or a horizontal lattice bar, the belts superimposed by a vertical strap (44). Portal support according to Claim 1 or 2, characterized in that the support post (3) is supported near its upper end by its rails (5), and the rigid member (5) is optionally supported by stiffening ribs (6). 4. A portal articulation device according to any one of claims 1 to 5, characterized in that the suspension member 17) for conveying couplings (8) to the saruclem (5)! is amplified. 5. A porous support structure according to any one of claims 1 to 5, characterized in that the switching dome (8) has an upper beam (81), a lower beam (82) and It comprises 10 adjustable switching members (83), the upper beam (81) and the lower beam (82) securing the saru member (5) by tensioning the switching member (83). 6. Portal structure according to any one of claims 1 to 4, characterized in that the lower belts (42) of the rectangular cross-member (4) are suspended on the upper belts (41) by a connecting rod (10) in the vicinity of the support column (3). Portal support according to claim 1, characterized in that the bridging beam (4) has two upper belts (41) and a lower belt (42), the upper belts (41) being a horizontal strap (43), the upper belt (43). The lower belt (42) is connected to each other (41) by an oblique strap (45). ²⁵ Portal support according to Claim 7, characterized in that the receiving unit (3a) at the upper end (3a) of the support column (3) is preferably a receiving unit of a size larger than the width of the bridging beam (4). the frame (15) is secured, and the adjustable support member (14) is inserted between the columns (153) of the frame (15) and the lower belt (42). 9. Portal support according to any one of claims 1 to 3, characterized in that the adjusting support member (14) is connected to the support post (3) or the lower belt (42) by means of a bracket (12) and its ends to the lower belts (42) or the support column (42). 3) they are tensioned against a reinforced stool (13). Portal support according to any one of claims 1-9, characterized in that the adjusting support member (14) is connected to the support post (3) or the suspension member (7) by means of a bracket (12) and its ends are connected to the suspension member. (7) or tensioned against a stool (13) mounted on an alarm column (3).