DE2022965A1 - Reinforced concrete structure - Google Patents

Description

I ; ■■ ' _u ', ..-; ·? May 8, 1970

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CIVIL & CIVIC PTY. LIMITED, Sidney, IT.S.W., Australia

Stylish concrete structure

The invention relates to a method for erecting structures.

Superstructures that are used in superstructures are those elements that are used to transmit their own dead load and other loads placed on the floor. The totality of all construction elements is referred to as construction. Structures are characterized by the material contained in these elements and the treatment that the Material experiences before or after its use in the construction elements.

Among the many types of structures are those who use steel and concrete in all possible combinations.

Known processes using steel and concrete, either independently from each other or in a compound part, se, use, have the disadvantage that some of the materials in the form used do not contribute their full load capacity, or the Components require temporary molding and / or support, or the components are very heavy and require high performance Ilebeanlagen, or the arrangement system hinders the

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Build speed. In addition, no known uses Procedure against the progressive degree of reinforcement in the hardening characteristics of the concrete.

The invention relates to the disadvantages mentioned To avoid methods of erecting structures and to use the progressive degree of reinforcement of the strength characteristics of the concrete vol ^ /.

The invention relates to a method for 'erecting structures using reinforced concrete. This process is independent of any temporary supporting mold for the cast Concrete, with reinforcing steel members used in the vertical and / or horizontal structural members and / or floors strong enough to support at least the damp concrete of the respective limb or floor, whereby the The method includes the steps of: placing the reinforcing steel in a position to pour the concrete to form the structural member and waiting for the concrete to harden over time before adding more members.

The invention relates to a method for erecting structures, which includes the advantages of known methods of using reinforced concrete in situ, with links in stages can be built into their final form, inder.i different materials be arranged in logical steps such that at each step the limbs are self-supporting and their maximum Contribute to the load-bearing capacity, including the concrete its progressive degree of reinforcement in strength, generally without the need for temporary shaping or · carriers. In particular, is in the vertical and / or

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Horizontal members and / or floors made of reinforcing steel members use, which are strong enough to support at least the damp concrete of the respective limb or floor .

One form of the method according to the invention consists in the following steps: arranging the primary reinforcing steel members in their length; _ä e, pouring the concrete to form the primary structural members and, following its progression over time, placing secondary members on the respective floor in the same way, primary members for the floor above, etc. with tertiary members if necessary, until the construction, including the floors, is completed.

The invention resides in a general form in a method the construction of a reinforced concrete member, in which only if active material is initially intended to to bear the loads that arise during part of the subsequent construction stages, additional material is added and gait, activated for step, to carry additional loads wear, and at least a part of the material acts in a way that supports the ab ".chi end e load from the beginning.

Other features, advantages and possible uses of the new Invention emerge from the accompanying illustrations of implementation examples as well as from the following description.

Show it:

Figure 1 is a top plan view of a typical building floor showing columns, primary beams, each supported on the columns by its "n ' , and secondary beams,." Each supported on beam beams at its ends, v < "i .'mGchaulicht ,

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Figure 2 is a section along the line 2-2 of Figure 1, Figure 3 is a section along the line 3-3 of Figure 1,

Figure A is a sectional view of a primary support beam, which also illustrates the connection with a secondary beam,

Figure 5 is a side view near the end of a primary Support beam,

Figure 6 shows a typical vertical section through a secondary beam,

Figure 7 is a side view of a portion of a secondary beam near its connection to one primary girder,

Figure 8 is a vertical section through 2 adjacent secondary beams and one associated therewith

FIG. 9 shows a perspective detailed view of a support beam-beam connection before pouring concrete,

Figure 10 shows a typical horizontal section through a column cladding, and

Figure 11 shows a connection between 2 parts of a column before the completion of the column.

Figures 1, 2 and 3 show a complete floor with columns, multiple girder beams, secondary beams and a ceiling.

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The main components of the primary beam A, shown in Figures 4 and 5, are a steel carriage along with concrete poured around the carriage. The team shown has an upper chord with spaced angles 13, a lower chord, consisting of 4 struts 14 and struts 15, which contain the tension net. The upper chord (not shown) can have transverse bracing in the horizontal plane, as can the lower chord. Vertical cross braces 16 can also be provided. All components are attached to one another by welding to form a rigid structure. Each end of each primary carriage is supported on an adjacent column (Figures 10 and 11) by means of coves 19 on the column with upright pins 20 each lying between the struts 14 of the primary support beam. Each pin 20 extends through a hole in a plate 21 (Figure 5) that is affixed to the underside of each pair of struts 14. At this stage the pillars are not filled with concrete and the primary harnesses are designed so that when, as described, supported in their final position in the structure, they are strong enough to withstand their own dead weight and any loads placed on them during to bear the planned sequence of the construction of the building. These loads include, for example, the dead weight of the beams as well as moving loads such as the weight of workers and construction equipment. Reinforced struts 22 and 23 are also placed in each primary beam prior to casting, as well as stirrups that are not part of the team and also carry a load until the concrete within the beam is poured and has developed sufficient strength to activate it. A typical combination for a secondary beam B is shown in FIGS. The top chord contains 2 parallel steel struts ? * Y arranged at a distance, to which short struts 26 are welded at intervals. The lower belt contains two similar struts 27 to which short struts 28 are attached at intervals. The network

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holds a strut 29, which at its connection with the Oborgurt around the strut 26, at its connection with the lower chord uu the strut 28 is bent. Reveal forms 30, which are usually Represent shells with a cross-section of an inverted ai U made of plastic, sheet metal or other suitable materials, extend between a secondary beam and the next. These are temporarily in their locations by means of Shells 31 held by your team by means of along the Length of the team spaced bolts 32 attached are. Blocks 33 and 33A, spaced along the trailer, separate the shell 31 from the lower belt struts 27 and receive the bolts 32. Each shell 31 may have flanges 35 of the Pick up shapes 30.

Next to the end of the girder harness adjacent the primary harnesses, two short struts 36 are welded to the net 29. The secondary pair is gehifcen to the primary yoke, said rods 36 rest on a angle 13 of the primary G _e instep, an assembly pin 37 at the angle 13 extends upwardly between the struts 36th

If necessary, spaced supports can be mounted across the top of the struts 36, between which the pin 37 also lies. This limits or prevents longitudinal movement of the secondary combination with respect to the primary combination. Reveal forms 30A (Figure 9)> similar in function to forms 30, are suspended from the primary harnesses in a Vifelse, which is similar to the suspension of the shells 31 or is made in some other way. An angle or end plate 27A is attached over the ends of the struts 2.1.

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The design of the primary and secondary teams is such that ircine beam supports are required around the shells 31 or wear the soffits 3OA ztj.

The teams can carry their own dead weight as well as the Concrete inside and any other stress that may

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is placed, / bif "to the point where the concrete has set. A suitable Arirderungsgitter 38 is carried on the top chord struts 25" .. of the "· ■" -auidary harnesses, initially as a tread / the egg; 'times access to to serve the ceiling, then, when connected to the upper chords of the secondary harnesses to serve as upper chord tension so that the harnesses do not warp when the wet concrete is placed on the ribbed ceiling, and Finally, to use al .: »Ceiling reinforcement when the concrete has set.

The column, e.g. 11, (Figures 10 and 11) is normally a vertical or nearly vertical link; their main function is to carry axial loads. In connection The column is one with the ncirte, multi-storey buildings vertical link as opposed to a girder, welher represents a horizontal link. ■

In common buildings, a concrete column is constructed as follows:

The reinforcing steel is brought into its position and fastened there, dar / Formwerk is built around the reinforcement and the Poured in concrete.

The reton in the column is given time to set and gain ruin or strength before being stressed.

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In the advancing strength system according to the invention, the construction of the column follows a different procedure »

An outer shell 43 with some or all of the necessary outer finish surface preparation is included in FIG Factory made. This shell can be referred to as a column housing will. The column housing is a reinforced concrete skin with thickened parts, specially designed and reinforced, to carry a specific load »The reinforcement at this stage contains the usual components ^ such as Struts and stirrups. A 'part of the reinforcement}, for example, the rods 44 and straps 45 are in the concrete of the housing used, but protrude into the room 46, which is later with concrete is filled.

After this column housing has hardened and has achieved the desired strength, it is lifted into the correct position and the remainder of the armor 47, 48, 49 for the complete column is inserted into the housing.

At this stage, the column housing is a complete, reinforced concrete element in a form by itself, which is suitable to be held in the final position in the overall structure and which is sufficiently strong and stiff, to carry their own weight during the construction without a carrier, any necessary, attached formwork, the rest Part of the reinforcement for the element, the wet concrete to complete the element and loads that occur during the Structure, including loads from other structural elements, for example loads from supported floors.

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The additional loads on the column housing need not be limited to loads of a single story. Addicted the pillar housing could be expected from the speed of the construction, laid on several floors To bear burdens. In all cases the column housing is designed to be used on its own, or with the help of one Part or all of the previously poured concrete in the casing that has acquired a certain strength, all To carry loads that come to the pillars in all stages of construction and loading »

The mechanism shown as screws 39 and 40 in Figure 11 is used to properly locate the lower end an upper pillar 11A with respect to the upper end of a lower pillar 11B. If Part 11A is properly related to the Part 11B is arranged, concrete can be poured to the Fill in the hollowed-out portion of the column 11A and insert it into the Overflow space adjacent ends 11A and 11B. Concrete loss A locking ring 41 prevents the gap from being reached.

The structure is as follows:

The prefabricated hollow concrete pillars 11 are in their final position arranged, both in relation to the lowermost column part and the position of an upper column part, such as the part 11A in relation to the underlying part 11B.

Each primary team is on a pillar at each end as described above.

Each end of each harness is supported on a primary harness as previously described.

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The carbon armor 3'8, or any other suitable Dedienaraiierungj, is placed on the upper straps of the harness worn =

Ede soffit forms 3OA are attached to the primary harnesses « The reveal forms 30 at the ends of the beam spans and adjacent to the connections with the primary teams are also brought into their position »

The pouring of the concrete can then begin »

Initially, the concrete is poured in, and the hollow pillars are rammed and finish the primary joists. When this concrete has set, the rest of the soffit shapes will be 30 placed in position for the secondary beams and cast the beams and ceiling 12 '.

The drawing "armored concrete" should ₅ , where used in the description and claims ₉ mean both usual reinforced concrete and "prestressed concrete"

The term "active material" means material which is able to load ₉ at any time to wear and part of the Endaufbaues wirdο the carriages for the primary beams and the secondary beams and the Säulengehause are examples of "active material" ,,

"Inactive material ' ⁸ is material which only bears a load after a certain time delay and then becomes"active'"- for example through" interaction with other material _o the reinforcement of the primary and secondary beams ", in contrast to the harnesses and wet concrete are examples of ^egg inactive material ⁰⁸ “When it sets, the concrete connects both active

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as well as inactive reinforcement to form a reinforced concrete plant, and creates extra strength as the concrete develops its strength. A benefit accrues from the progression Development of strength in each element of the structure in order to superimpose further vertical and horizontal elements and / or to allow material while achieving the required strength.

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Claims (1)

Claims 1./Method for the construction of a reinforced concrete structure member, thereby characterized as having only enough active material initially is provided to carry the loads imposed during part of the subsequent construction stages, that further Material is added and activated step by step to trap additional loads, and that! At least one Part of the material acts from the start in a manner bearing the final load. 2. Reinforced concrete member made by the method of claim 1. 3. structural member according to claim 2, characterized in that it is a support beam » 4. structural member according to claim 2, characterized in that it is a side beam and a ceiling member. 5. structural member according to claim 2 _P, characterized in that it is a column or a wall. 6. A method for producing a reinforced concrete construction _{element, characterized in 9} that a first part of the reinforcement is provided for the complete element in a form which is held in its end position in the overall structure and is sufficiently firm and stiff, during the construction without additional supports other than its final supports bear their own weight, any necessary formwork attached, as well as loads that 0098 k 7/1301 21) 22965 applied during construction, including the Loads from other structural members, the remaining part of the reinforcement for the element and the wet concrete to complete of the element that one has the first part of the reinforcement at or near its support points throughout Structure supports that one attaches the formwork that one arranges and attaches the remaining part of the reinforcement that one pour the concrete to complete the element and that the element is allowed to set before additional Loads of further material are applied in further elements. 7 Reinforced concrete structural member manufactured according to the method of claim 6. 8. structural member according to claim 7, characterized in that it is a support beam. 9. structural member according to claim 7, characterized in that it is a secondary beam and a ceiling member. 10. structural member according to claim 7, characterized in that »that it is a pillar or a wall. 11. Reinforced concrete structural element, characterized in that at least a first part of the reinforcement is in itself initially a complete structural element in a form which are kept in their final position in the overall structure can and eat enough feat and steiff to eat during the Structure without additional supports other than their final supports their own weight, any necessary, attached formwork, as well as loads that can be carried during the application ο ο 9 η ι, 7/13 o 1 2UZ296b construction, including loads from others partial or complete structural elements, the remaining part of the reinforcement for the element and the wet concrete to complete the element at least partially 12. Structural element according to claim H _9, characterized in that the element in its closing position in the completed structure is a supporting beam or a secondary beam » 13ο structural element according to claim 12, characterized in that the first part of the reinforcement is a team » 14ο structural element according to claim 11, characterized in that it is a column or a wall » ο Structure element according to claim 11, characterized in that it is a secondary beam or a ceiling element. 16 ο Reinforced concrete structure, characterized by spaced rows of columns, support beam according to claim 12, held on at least 2 columns in a row, - a support beam according to claim 12, held on at least 2 columns in adjacent rows and by a secondary beam and a ceiling according to claim 15, held on and between the support beams o 17 ° reinforced concrete structural element, characterized in that at least a first part of the reinforcement for itself initially is a complete structural element in egg form, which are kept in their final position in the ik-m overall structure can be and is strong enough and ο te iff to during 0 0 9 8 A 7 / I 3 0 I ■ 8AD OR] GiNAL ■ ν - 2Ü2296B - 15 - of the structure without additional supports other than the final supports bear their own weight, any necessary formwork, and loads placed on them during the Superstructure, including the loads from other partial or complete superstructure members., the remaining part of the reinforcement, the wet concrete for partial or complete completion of the element, and that the setting process of the concrete progresses with the element Increase in strength and ability provides more loads applied by more elements be withstood while achieving the required strength. 18. Method for erecting a reinforced concrete structure, thereby that items are in their final location erected without additional supports other than the final supports where there is only enough active material in the beginning Each element is designed to carry the stresses of the next stage of construction, and that progressive addition of further material element by element, allowing each element to progressively solidify and the additional ones To bear loads that are applied by further, additional material in further elements, until each element is complete and sufficiently strong and stiff to bear all the loads for which the structure is built is designed. 19. Reinforced gate concrete structure, erected according to the method of claim 18th 20. Structure according to ^ nrspruch 19, characterized in that it is a Girder balcony 1/31. 0098 / .7 / 1301 8AO ORiGiNAL 202296b 21. Structure according to claim 19, characterized in that it is a secondary beam and a ceiling structure. 22. Structure according to claim 19, characterized in that it has a Pillar or wall. η ο ii n /, 7/13 0 1