DE212021000266U1 - Connection structure for the realization of an exact positioning of a concrete-filled spatial structure made of multi-part steel tubes and a supporting platform - Google Patents

Abstract

Connection structure for the realization of an exact positioning of a concrete-filled spatial structure made of multi-part steel tubes and a supporting platform, characterized in that it comprises a concrete supporting platform (1), several supporting tubular steel units (29) arranged on the concrete supporting platform (1), one arranged on the concrete supporting platform (1), a steel base unit (3) located between the plurality of structural steel tube units (2), an anchoring steel unit (4) disposed in the concrete support platform (1) for connecting and reinforcing the structural steel tube units (2) and the steel base unit (3), a steel base unit (3) and a connecting steel pipe (5) arranged on the supporting steel pipe units (2) and a concrete pouring block (6) arranged on the concrete supporting platform (1) whose upper surface is higher than the height of the upper end of the connecting steel pipe (5).

Description

TECHNICAL AREA

The present invention relates to the technical field of bridge construction, in particular a connection structure for realizing precise positioning of a concrete-filled spatial structure made of multi-part steel tubes and a supporting platform.

STATE OF THE ART

The concrete-filled multi-span steel tube structure mainly includes load-bearing steel tubes and concrete support seats, and is generally used for the compression arch rib of long-span arch bridges. In addition, the multi-section steel pipe structure can further improve the support strength, and finally the whole multi-section steel pipe support structure has the advantages of strong initial impact resistance, good seismic resistance, excellent fire resistance and corrosion resistance, and moderate design difficulties.

On the other hand, most of the existing multi-section steel pipe structures have a certain degree of insufficient joint strength between the steel pipes and the concrete main body, ultimately resulting in the multi-section steel pipes not being able to bear a large weight for a long time and under high loads.

In summary, therefore, there is an urgent need for a support seat for multi-section steel pipes, which can enhance the connection strength between steel pipes and concrete so that the whole support structure has better integrity and support strength.

The Chinese utility model patent with the patent notification number CN207419230U and the announcement date 29.05.2018 discloses a multi-section hollow composite tower pillar, wherein the tower pillar consists of multi-section tower pillars or pillar pillars having at least one limb, the respective tower pillars or pillar pillars being connected to each other by the cross braces, and the respective tower pillars or pillar pillars in the form of double-layer steel tubes, and wherein the tower column or pillar column is spliced at the top and bottom by a tower column or pillar column segment provided with ventilation holes and a tower column or pillar column segment not provided with ventilation holes, and the bottom part of the tower column or pillar column segment provided with ventilation holes is provided with the Support platform connected and the upper part is connected to the lower part of the provided with no ventilation holes tower column or pillar column segment, and wherein the tower column or pillar column segments by anchoring ku rzen prestressed steel bars and full-length prestressed steel bars going through the entire tower column or pier column.

However, in the multi-section hollow composite pier in this utility model patent, the piers are connected only by the cross braces. Although the strength between the tower pillars can be reasonably improved in this way, the gap between the tower pillars and the supporting platform still lacks a connection structure, a position of the tower pillar close to the supporting platform can still bend slightly, so that the integrity of the whole Tower pillar is not sufficient and also its support strength is not enough, and the relatively short-term use under high load will cause the problem of cracking and breaking of the tower pillar structure.

CONTENT OF THE PRESENT INVENTION

The present invention provides a connection structure for realizing accurate positioning of a concrete-filled space structure made of multi-section steel pipes and a supporting platform, on which concrete supporting platform a supporting steel pipe unit, a steel base unit, an anchoring steel unit, a connecting steel pipe and a concrete pouring block are arranged to achieve the purpose that the concrete-filled structure made of multi-section steel tubes can be used for relatively long-term high-strength support.

In order to solve the above technical problem, the present invention uses the following technical solution: a connection structure for realizing accurate positioning of a concrete-filled space structure made of multi-section steel pipes and a supporting platform, comprising a concrete supporting platform, a plurality of supporting steel pipe units arranged on the concrete supporting platform, one on the concrete supporting platform a steel base unit disposed between the plurality of structural steel pipe units, an anchoring steel unit disposed in the concrete supporting platform for connecting and reinforcing the structural steel pipe units and the steel base unit, a connecting steel pipe disposed between the steel base unit and the structural steel pipe units, and a concrete pouring block disposed on the concrete supporting platform, the top surface thereof is higher than the height of the top end of the connecting steel pipe.

Another preferred technical solution is that the supporting steel pipe unit comprises a steel pipe body used for installing the connecting steel pipe with a lower end arranged on the upper surface of the concrete supporting platform, steel pipe concrete arranged in the steel pipe body, and a steel pipe shearing element arranged on the steel pipe body for strengthening the connection in the concrete casting block.

Another preferred technical solution is that all supporting tubular steel units are arranged in a center-symmetrical distribution with respect to the basic steel unit.

Another preferred technical solution is that the steel base unit has a base steel plate arranged on the upper surface of the concrete supporting platform, a hemispherical steel block arranged on the upper surface of the base steel plate with a spherical surface used for installing the connecting steel pipe, and a steel block arranged on the hemispherical one for reinforcing the Base shear element used in the concrete pouring block.

Another preferred technical solution is that the anchoring steel unit comprises an anchoring base plate arranged in the concrete supporting platform, a threaded column arranged at the middle position of the upper surface of the anchoring base plate and used for connecting with the base steel plate, and a reinforcing member arranged at the position of the side edge of the upper surface of the anchoring base plate , which is inserted into the steel pipe concrete for reinforcing the steel pipe body.

Another preferred technical solution is that the reinforcement element is a profile steel or a steel bar.

Another preferred technical solution is that the supporting steel pipe unit further comprises a steel pipe hole provided on the steel pipe body, used for inserting and installing the steel pipe shearing member, and the anchoring steel unit further includes a steel pipe hole provided on the reinforcing member, used for inserting and installing the steel pipe shearing member Steel plate hole included.

Another preferred technical solution is that the height of the top end surface of the tubular steel concrete is greater than the height of the top surface of the concrete casting block.

Another preferred technical solution is that the height of the top end surface of the tubular steel concrete is greater than the height of the top surface of the concrete casting block.

• S1: Installieren und Verbinden der Verankerungsstahleinheit und Gießen von Beton auf die Verankerungsstahleinheit, um die Betontragplattform zu bilden, wodurch eine Betonstützbasis erhalten wird;
• S2: Installieren der Stahlbasiseinheit auf der Betonstützbasis, um den vorläufigen Hauptkörper des mehrgliedrigen Stahlrohrs zu erhalten;
• S3: Installieren des Stahlrohrkörpers der tragenden Stahlrohreinheit und des Verbindungsstahlrohrs auf dem vorläufigen Hauptkörper des mehrgliedrigen Stahlrohrs, um den mittelfristigen Hauptkörper des mehrgliedrigen Stahlrohrs zu erhalten;
• S4: Gießen des Stahlrohrbetons in die tragende Stahlrohreinheit des mittelfristigen Hauptkörpers des mehrgliedrigen Stahlrohrs, um den Hauptkörper der späteren Stufe des mehrgliedrigen Stahlrohrs zu erhalten;
• S5: Gießen und Formen des Betongießblock s auf dem Hauptkörper der späteren Stufe des mehrgliedrigen Stahlrohrs, um die endgültige betongefüllte Struktur aus mehrgliedrigen Stahlrohren zu erhalten.

A construction method of a connecting structure for realizing an accurate positioning of a concrete-filled space structure made of multi-section steel tubes and a supporting platform, comprising the following steps in sequence:

• S1: installing and connecting the anchor steel unit and pouring concrete on the anchor steel unit to form the concrete support platform, thereby obtaining a concrete support base;
• S2: Installing the steel base unit on the concrete support base to obtain the temporary main body of the multi-section steel pipe;
• S3: Installing the steel pipe body of the supporting steel pipe unit and the connecting steel pipe on the temporary main body of the multi-section steel pipe to obtain the middle-term main body of the multi-section steel pipe;
• S4: pouring the steel pipe concrete into the supporting steel pipe unit of the middle-stage main body of the multi-section steel pipe to obtain the main body of the later stage of the multi-section steel pipe;
• S5: Casting and molding of the concrete ingot on the main body of the later stage of the multi-section steel pipe to obtain the final concrete-filled multi-section steel pipe structure.

beneficial effects

The present invention has the following advantages: 1. the concrete-filled multi-section steel pipe structure has good integrity, the internal connection structure has high strength, and it is not easy to break and disassemble after long-term support and heavy-load use; 2. the multi-section steel tubes are arranged evenly and symmetrically, and the overall connection strength is strengthened by the connecting steel tube to ensure that the entire supporting structure is evenly loaded and supported; 3. The construction method of the whole concrete-filled multi-section steel pipe structure mostly adopts welding and casting technology, and the whole structure layout is also reasonable, which ultimately ensures the construction operation is simple and highly efficient.

character list

• 1 Figure 12 shows a schematic diagram of the use of a concrete filled structure made of multi-section steel tubes according to the present invention.
• 2 Fig. 12 shows a schematic diagram of a first distribution manner of a plurality of supporting steel pipe units in a plan view according to the present invention.
• 3 Fig. 12 shows a schematic structural view of the positions of a supporting steel tube unit, a steel base unit and an anchoring steel unit according to the present invention.
• 4 Fig. 12 shows a schematic diagram of a connection structure between the steel pipe shearing member and the reinforcing steel plate according to the present invention.
• 5 Fig. 12 shows a schematic diagram of a second way of distributing multiple supporting steel pipe units in a plan view according to the present invention.
• 6 Fig. 12 shows a schematic diagram of a third way of distributing multiple supporting steel pipe units in a plan view according to the present invention.

DETAILED DESCRIPTION

Only preferred exemplary embodiments of the present invention are explained in more detail below; the scope of the present invention is not restricted thereto.

Example: as in 1 , 2 , 3 , 4 , 5 and 6 shown, a connection structure for the realization of an exact positioning of a concrete-filled spatial structure made of multi-part steel tubes and a supporting platform, comprising a concrete supporting platform 1, a plurality of supporting steel tube units 2 arranged on the concrete supporting platform 1, a steel base unit 3 arranged on the concrete supporting platform 1 and located between the plurality of supporting steel tube units 2 , an anchoring steel unit 4 arranged in the concrete supporting platform 1 for connecting and reinforcing the supporting steel pipe units 2 and the steel base unit 3, a connecting steel pipe 5 arranged between the steel base unit 3 and the supporting steel pipe units 2, and a concrete pouring block 6 arranged on the concrete supporting platform 1, the upper surface of which is higher than is the height of the top end of the connection steel pipe 5 .

In the present embodiment, the supporting steel pipe unit 2, the steel base unit, the anchoring steel unit 4 and the connecting steel pipe 5 form a complete steel structure to ensure the support strength, and the concrete support platform 1 is cast first to install the above steel structure, then the concrete casting block 6 cast to reinforce the above steel structure, so that the whole concrete-filled multi-section steel pipe structure has high structural strength when used as a bridge support, which allows large loads and has the advantage of long-term stable use.

The structural steel pipe unit 2 comprises a steel pipe body 201 used for installing the connecting steel pipe 5 having a lower end arranged on the upper surface of the concrete supporting platform 1, steel pipe concrete 202 arranged in the steel pipe body 201, and a steel pipe shearing member 203 arranged on the steel pipe body 201 for strengthening the connection in the concrete casting block 6.

In the present embodiment, the above-mentioned steel structures are made of existing high-strength steel, and the concrete materials used for the steel pipe concrete 202, the concrete support platform 1 and the concrete pouring block 6 are existing suitable high-strength concrete.

It is feasible that the distance between the upper ends of any two structural steel pipe units 2 is larger or smaller than the distance between the lower ends.

In the present embodiment, the multiple steel pipe bodies 201 may be “expanded” or “contracted” like “flowers”.

All supporting tubular steel units 2 are arranged in a center-symmetrical distribution with respect to the basic steel unit 3 .

In the present embodiment, they can also be arranged linearly or arranged in a circle to form a trapezoid in plan view, as in FIG 5 and 6 shown.

The steel base unit 3 comprises a base steel plate 301 arranged on the upper surface of the concrete supporting platform 1, a hemispherical steel block 302 arranged on the upper surface of the base steel plate 301 with a spherical surface used for installing the connecting steel pipe 5, and one arranged on the hemispherical steel block 302 to reinforce the connection Basic shear element 303 used in the concrete casting block 6.

In the present embodiment, the hemispherical steel block 302 may be solid or open as long as the connecting steel pipe 5 can be stably welded and fixed, and the base shearing member 303 and the steel pipe shearing member 203 have the same structure and are each formed into a T-shape, which ensures that the tubular steel body 201 and the hemispherical steel block 302 can be "pulled" respectively in the concrete casting block 6 formed later.

The anchoring steel unit 4 comprises an anchoring base plate 401 arranged in the concrete supporting platform 1, a threaded column 402 arranged at the center position of the upper surface of the anchoring base plate 401 and used for connection with the base steel plate 301, and a reinforcing member 403 arranged at the position of the side edge of the upper surface of the anchoring base plate 401 , which is inserted into the steel pipe concrete 202 to reinforce the steel pipe body 201 .

In the present embodiment, the base steel plate 301 is provided with an opening for inserting the threaded column 402 and a mating fastening nut. The thread columns 402 are provided in a number of 4 and are used for bolting to the four corners of the base steel plate 301 stably.

In addition, the structure of the reinforcing member 403 may also be tubular as long as it is ensured that the reinforcing member 403 can be “pulled” through the steel pipe concrete 202 stably.

Finally, both the threaded column 402 and the reinforcing member 403 are welded to the upper surface of the anchoring base plate 401, and the welding angle depends on the inclination angle of the steel pipe body 201, and the reinforcing member 403 is located in the steel pipe body 201 at the middle position as much as possible, to ensure that the "pull" structure mentioned above has the effect of uniform loading.

The reinforcement element 403 is a section steel or a steel rod. In the present embodiment, the functions of the reinforcing member 403 and the connection steel pipe 5 are basically the same, namely, both are intended to reinforce the steel pipe body 201 . Therefore, the reinforcement member 403 is set relatively low, which can ensure that the connection and reinforcement effect with the connection steel pipe 5 has the advantage of being divided into upper and lower areas and coordinated use to avoid the harmful problem that the connection steel pipe 5 pulls and fixes the reinforcing member 403 and thus is not conducive to the reinforcement of the steel pipe body 201.

The supporting steel pipe unit 2 further includes a steel pipe hole 204 provided on the steel pipe body 201 and used for inserting and installing the steel pipe shearing member 203, while the anchoring steel unit 4 further includes a steel plate hole 404 provided on the reinforcing member 403 and used for inserting and installing the steel pipe shearing member 203 includes.

In the present embodiment, the reinforcing members 403 may be provided in a number of 1-4, so that 1-4 rows of the steel pipe shearing members 203 are also arranged on the steel pipe body 201 accordingly, to ensure that each steel pipe shearing member 203 after passing through the steel pipe hole 204 can be inserted into the steel plate hole 404, so that the reinforcing member 403 has the following two fixing structures: first, it is fixed through the steel pipe concrete 202, second, it is inserted and fixed through the steel pipe shearing member 203, so that the reinforcing member 403 and the tubular steel body 201 can be better integrated to ensure the benefits of ultimate structural integrity and high strength.

The height of the top end face of the steel pipe concrete 202 is greater than the height of the top surface of the concrete casting block 6.

In the present embodiment, the position between the tubular steel body 201 and the top surface of the concrete pouring block 6 is the part where the force is most concentrated, and this part is the most likely to fail the tubular steel body 201, so the pouring amount of the tubular steel concrete 202 is set relatively large , so that the upper end face of the steel tube concrete 202 is higher than the upper surface of the concrete pouring block 6, resulting in the force causing the above bending effect being "carried" by the steel tube body 201 and the steel tube concrete 202 together, in the way the support strength of the structural steel pipe unit 2 can be further enhanced.

• S1: Installieren und Verbinden der Verankerungsstahleinheit 4 und Gießen von Beton auf die Verankerungsstahleinheit 4, um die Betontragplattform 1 zu bilden, wodurch eine Betonstützbasis erhalten wird;
• S2: Installieren der Stahlbasiseinheit 3 auf der Betonstützbasis, um den vorläufigen Hauptkörper des mehrgliedrigen Stahlrohrs zu erhalten;
• S3: Installieren des Stahlrohrkörpers der tragenden Stahlrohreinheit 2 und des Verbindungsstahlrohrs 5 auf dem vorläufigen Hauptkörper des mehrgliedrigen Stahlrohrs, um den mittelfristigen Hauptkörper des mehrgliedrigen Stahlrohrs zu erhalten;
• S4: Gießen des Stahlrohrbetons 202 in die tragende Stahlrohreinheit 2 des mittelfristigen Hauptkörpers des mehrgliedrigen Stahlrohrs, um den Hauptkörper der späteren Stufe des mehrgliedrigen Stahlrohrs zu erhalten;
• S5: Gießen und Formen des Betongießblocks 6 auf dem Hauptkörper der späteren Stufe des mehrgliedrigen Stahlrohrs, um die endgültige betongefüllte Struktur aus mehrgliedrigen Stahlrohren zu erhalten.

A construction method of a connecting structure for realizing an accurate positioning of a concrete-filled space structure made of multi-section steel tubes and a supporting platform, comprising the following steps in sequence:

• S1: installing and connecting the anchor steel unit 4 and pouring concrete on the anchor steel unit 4 to form the concrete support platform 1, thereby obtaining a concrete supporting base;
• S2: installing the steel base unit 3 on the concrete support base to obtain the temporary main body of the multi-section steel pipe;
• S3: installing the steel pipe body of the structural steel pipe unit 2 and the connecting steel pipe 5 on the temporary main body of the multi-part steel pipe to obtain the intermediate main body of the multi-part steel pipe;
• S4: Pouring the steel pipe concrete 202 into the supporting steel pipe unit 2 of the middle-stage main body of the multi-section steel pipe to obtain the main body of the later stage of the multi-section steel pipe;
• S5: Pouring and molding of the concrete ingot 6 on the main body of the later stage of the multi-section steel pipe to obtain the final concrete-filled multi-section steel pipe structure.

In the present embodiment, the steel pipe shearing member 203 is first inserted into the reinforcing member 403, and then the steel pipe concrete 202 is poured, so that the structures of the anchor steel unit 4 and the supporting steel pipe unit 2 are fixed, but they cannot be heavily loaded at this time , and they can be used with a temporary tubular steel support frame.

The steel pipe concrete 202 can be poured into the opening of the upper end of the steel pipe body 201 .

Subsequently, the connecting steel pipe 5 is welded, and finally the concrete pouring block 6 is poured, so that the outside of the entire concrete-filled multi-section steel pipe structure still has a concrete “frame”, which improves the overall strength of the concrete-filled multi-section steel pipe structure. Of course, when the concrete-filled structure of steel multi-member pipes is used, a load must be installed on the supporting steel pipe unit 2 in order to use the concrete-filled structure of steel multi-member pipes.

The embodiments of the present invention are explained in more detail below in connection with figures, but the present invention is not limited to the embodiments described above. Various changes can be made within the scope of the knowledge of those skilled in the art without departing from the principle of the present invention. These are all non-creative changes, as long as they come within the scope of the claims of the present invention, they are protected by patents.

QUOTES INCLUDED IN DESCRIPTION

This list of documents cited by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Patent Literature Cited

• CN 207419230 U [0005]

Claims (8)

Connection structure for the realization of an exact positioning of a concrete-filled spatial structure made of multi-part steel tubes and a supporting platform, characterized in that it comprises a concrete supporting platform (1), several supporting tubular steel units (29) arranged on the concrete supporting platform (1), one arranged on the concrete supporting platform (1), a steel base unit (3) located between the plurality of structural steel tube units (2), an anchoring steel unit (4) disposed in the concrete support platform (1) for connecting and reinforcing the structural steel tube units (2) and the steel base unit (3), a steel base unit (3) and a connecting steel pipe (5) arranged on the supporting steel pipe units (2) and a concrete pouring block (6) arranged on the concrete supporting platform (1) whose upper surface is higher than the height of the upper end of the connecting steel pipe (5). Connection structure for the realization of an exact positioning of a concrete-filled spatial structure made of multi-part steel tubes and a supporting platform claim 1 , characterized in that the supporting steel pipe unit (2) has a steel pipe body (201) used for installing the connecting steel pipe (5) with a lower end arranged on the upper surface of the concrete supporting platform (1), steel pipe concrete (202) arranged in the steel pipe body (201). and a steel pipe shearing element (203) arranged on the steel pipe body (201) for strengthening the connection in the concrete casting block (6). Connection structure for the realization of an exact positioning of a concrete-filled spatial structure made of multi-part steel tubes and a supporting platform claim 1 , characterized in that all supporting tubular steel units (2) are arranged in a centre-symmetrical distribution with respect to the basic steel unit (3). Connection structure for the realization of an exact positioning of a concrete-filled spatial structure made of multi-part steel tubes and a supporting platform claim 2 , characterized in that the steel base unit (3) comprises a base steel plate (301) arranged on the upper surface of the concrete supporting platform (1), a hemispherical steel block (302) arranged on the upper surface of the base steel plate (301) with a connecting steel pipe (5 ) used spherical surface and a base shear element (303) arranged on the hemispherical steel block (302) and used for strengthening the connection in the concrete casting block (6). Connection structure for the realization of an exact positioning of a concrete-filled spatial structure made of multi-part steel tubes and a supporting platform claim 4 , characterized in that the anchoring steel unit (4) comprises an anchoring base plate (401) arranged in the concrete supporting platform (1), a threaded column (402) arranged at the middle position of the upper surface of the anchoring base plate (401) and used for connection with the base steel plate (301) and a reinforcing member (403) arranged at the position of the side edge of the upper surface of the anchoring base plate (401) and inserted into the steel pipe concrete (202) for reinforcing the steel pipe body (201). Connection structure for the realization of an exact positioning of a concrete-filled spatial structure made of multi-part steel tubes and a supporting platform claim 5 , characterized in that the reinforcing element (403) is a profile steel or a steel bar. Connection structure for the realization of an exact positioning of a concrete-filled spatial structure made of multi-part steel tubes and a supporting platform claim 5 , characterized in that the supporting steel pipe unit (2) further comprises a steel pipe hole (204) provided on the steel pipe body (201) and used for inserting and installing the steel pipe shearing member (203), wherein the anchoring steel unit (4) further comprises a steel pipe attached to the reinforcing member (403) steel plate hole (404) used for inserting and installing the steel pipe shearing member (203). Connection structure for the realization of an exact positioning of a concrete-filled spatial structure made of multi-part steel tubes and a supporting platform claim 2 , characterized in that the height of the top end surface of the tubular steel concrete (202) is greater than the height of the top surface of the concrete casting block (6).

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