EA009137B1 - Method for fabricating building structures and building structure fabricated using same - Google Patents

Abstract

The invention relates to construction industry, in particular, to methods of fabricating concrete and reinforced concrete articles, more definite, to methods for fabricating building structures, preferably, hollow plates using an extruder. The method for fabricating building structures, mainly hollow plates by extrusion on a production line comprises framework with a pallet and an extruder with a hopper for hardening material and a working member, the method comprises steps of mounting a framework on a pallet, charging the hardening material to the hopper, filling the framework, consolidation and forming, wherein the extruder working member is used for consolidating and forming of the hardening material, the working member comprises at least one working member which has a housing, a void former, hollow blade screw, outer and inner spindles arranged coaxially to the guide stem, wherein one spindle can rotate, the axial vibration is transferred to the other, the rotatable spindle transfers rotation to the other via a device which provides free movement of the spindles towards each other in axial direction, wherein the second spindles is rigidly coupled with the screw, and the screw is hingedly connected to the void former fixed on the stem adapted to only axial movements. The technical result is aimed at providing higher quality of reinforced concrete articles, higher concrete consistency and strength due to increase of plasticity and decrease of friction properties of concrete mixture on boundaries separating the concrete mixture and working surfaces of void formers and the extruder screw blade.

Description

The invention relates to the field of construction, and in particular to methods of manufacturing building structures, mainly hollow-core slabs, using an extruder.

In the prior art, building structures and a method for manufacturing building structures, mainly hollow-core slabs, are extruded on a production line, including formwork with a pallet and an extruder with a hopper for hardening material and a working body (see EP 0152166 A1, 08.21.1985, B 28B 7 / thirty).

In the prior art, building structures and a method of manufacturing these building structures, mainly hollow-core slabs, are extruded on a production line containing at least an extruder with a hopper for hardening material and a formwork in the form of a pallet (see KI 2013205 C1, 08.23.1985, 28B 5/02).

The disadvantages of the known methods and structures, respectively, is the low quality of the extrusion of concrete into the product and the low productivity of supplying concrete per unit capacity of the extruder with insufficient density and strength of concrete in the fabricated structure due to the irrational extrusion system for feeding and laying concrete, which does not have longitudinal axial vibration processing of concrete output from the extruder.

The task for which the present inventions are directed is to increase the productivity of the method and the quality of the products manufactured by it.

The task is solved due to the fact that in the method of manufacturing building structures, mainly hollow-core slabs, extrusion on the production line, including formwork with a pallet and an extruder with a hopper for hardening material and a working body, according to the invention provides for the installation of reinforcement on the pallet formwork, loading hardening material into the bunker and its supply to the formwork pallet with compaction and molding, and an extruder is used for compaction and molding of hardening material an era consisting of at least one working element comprising a housing, an emptying coaxially mounted coaxially to the guide rod, a hollow propeller screw, external and internal spindles, one of the spindles being rotated and axial vibration transmitted to the second spindle, the rotating spindle transmitting the rotation to the other by means of a device that ensures the free movement of the spindles relative to each other in the axial direction, with the spindle to which the axial vibration is transmitted, as well as the rotation, It is connected to the auger, and the auger to the free end is pivotally connected to a core former fixed to the rod with the possibility of only axial vibrations.

During the extrusion of hardening material, the extruder can move above the formwork due to pushing away from the compacted hardening material.

They can rotate the external spindle, and transfer the internal vibration to the internal one, and transmit the internal rotation from the external spindle by means of a device, for example, as a tooth on one spindle, which enters an axially extended groove of another spindle, or by means of a key installed in an axially extended direction grooves spindles.

The screw can be rigidly attached to the internal spindle.

They can rotate the internal spindle, and transmit the external vibration to the external one, whereby the internal spindle is transmitted to external rotation by means of a device, for example, in the form of a tooth on one spindle, which enters the axially extended groove of another spindle, or by means of a key installed in the axially extended grooves spindles.

In this case, it is preferable that the screw was rigidly attached to an external spindle.

Heavy concrete may be used as a hardening material.

On the production line, they can manufacture prestressed building structures, for which, before extrusion of hardening material, the reinforcement is strained.

They can use a core former with a thickness that is less than the thickness of a moldable building structure.

On a production line, they can produce building structures in the form of hollow plates, mainly with round or oval cavities in cross-section, for which they use a round-shaped or oval-shaped cross-section.

On a production line, they can produce building structures in the form of hollow plates with voids in cross section in the form of a rectangle, triangle or star with rounded corners. For this, they use a core former with a cross section in the form of a rectangle, triangle or star with rounded corners.

They can use a core former with a thickness of at least the thickness of the moldable building structure.

On the production line can produce extensive building structures, for example, I-beams.

An extruder tool can be used, consisting of at least two working elements, and the auger blade of each neighboring work element has the opposite direction of rotation.

In the manner described above, the building structure is made, which is the second

- 1 009137 dependent object of the invention.

The technical result achieved by the invention is to provide higher quality molded concrete products, increase the density and strength of concrete in the product due to the increase in plasticity and reduce the frictional properties of the supplied concrete mix directly at the interfaces of the concrete mix and in contact with it working surfaces of hollow cores and spiral blades extruder screw.

The invention is illustrated by drawings, where in FIG. 1 shows an extruder, a longitudinal section;

in fig. 2 - a fragment of the working body of the extruder, side view with a partial cut;

in fig. 3 - a fragment of the working body, top view;

in fig. 4 is a cross section of an extruder in the area of the chain transmission;

in fig. 5 is a working element, side view with a partial cut;

in fig. 6 — node A in FIG. five;

in fig. 7 - extruder made differently - the second option, a perspective view;

in fig. 8 - a fragment of the working body of the extruder according to the second variant, side view with a partial cut;

in fig. 9 - extended I-beams manufactured on the production line, cross-section;

in fig. 10 - long beam constructions made on the production line, cross section;

in fig. 11-16 - fragments manufactured on the technological line of building structures in the form of hollow plates with different voids in cross section.

A method of manufacturing building structures 1 by extrusion on a production line (not shown), comprising a formwork (not shown) with a pallet (not shown) and an extruder 2, including a hopper 4 for a hardening material, such as heavy concrete, mounted on a supporting frame 3 the body 5, consisting of one working element 6, comprising a housing 7 mounted coaxially with the guide rod 8, a hollow core 9, a hollow bladed screw 10, external and internal spindles respectively 11 and 12. The method involves the installation reinforcement (not shown) on the pallet (not shown) formwork (not shown), loading of hardening material into the hopper 4 and feeding it to the pallet (not shown) formwork with compaction and molding. For compaction and molding of hardening material using the working body 5 of the extruder 2, consisting of at least one working element 7, comprising a housing 8, installed coaxially to the guide rod 8 hollow core 9, hollow vane screw 10, outer 11 and internal spindles 12. One of the spindles , for example external 11, rotate, and on the second - internal spindle 12 transmit axial vibration. In this case, the rotatable outer spindle 11 transfers the rotation to the inner spindle 12 by means of a device that ensures free movement of the spindles relative to each other in the axial direction, for example, by means of a key 13 installed in the axially extended grooves 14 of the spindles 11 and 12.

The internal spindle 12, which transmit axial vibration, as well as rotation, is rigidly connected to the propeller screw 10, and the screw 10 with its free end pivotally connected to the core former 9 fixed on the rod 8 with the possibility of only axial oscillations.

Or use an extruder in which the inner spindle 12 rotates, and on the second - the outer spindle 11 transmit axial vibration. At the same time, the rotated inner spindle 11 transfers the rotation to the outer spindle 12 by means of a device that ensures free movement of the spindles relative to each other in the axial direction, for example, or by means of a key 13 installed in the axially extended grooves 14 of the spindles 11 and 12.

External spindle 11, which transmit axial vibration, as well as rotation, is rigidly connected with the blade screw 10, and the screw 10 with its free end pivotally connected to the core former 9 fixed on the rod 8 with the possibility of only axial oscillations.

Use the working body 5 of the extruder 2, consisting of a pole work item 6, and the blade of the screw 10 of each adjacent work item 6 has the opposite direction of rotation.

During the extrusion of hardening material, the extruder moves over the formwork due to pushing away from the compacted hardening material.

On the production line, prestressed building structures are manufactured 1 for which, before extrusion of hardening material, reinforcement is strained.

They can use the core former 9 with a thickness of lesser thickness and formable building structure 1.

On the production line, building structures 1 are made in the form of hollow plates 15 mainly with round 16 or oval 17 in the cross section of the voids, for which use is made of a round or oval hollow core 9.

Or on the production line (not shown) make building structures in the form of hollow plates 15 with voids in cross section in the form of a rectangle 18, triangles

- 009137 ka 19 or stars with rounded corners (not shown), for which use a hollow core with a cross-section in the form of a rectangle, triangle or star with rounded corners (not shown in the drawings).

Or they can use a core former with a thickness not smaller than that of a formable building structure 1.

On the production line, extensive building structures are made, for example, beams 20, including I-beams 21.

The extruder in the implementation of the method works, for example, as follows.

From the motor, a sprocket made for an chain transfer is transmitted to the external spindle via a device for rotating an external spindle.

The hydraulic system, which includes a hydraulic station (not shown in the drawings), through a distributor by rotating the rotor (not shown in the drawings) applies pressure of the hydraulic fluid to the piston rod and produces axial vibration transmitted to the internal spindle.

Rotation of the rotor (not shown) of the distributor of the hydraulic system (not shown) is carried out by means of a belt drive from the engine onto a pulley attached to the rotation (not shown).

From the external spindle, rotation is transmitted to the internal spindle. The device is made in the form of a tooth (not shown in the drawings) on one spindle, which is included in the axially extended groove of the other spindle and allows the spindles to freely move relative to each other in the axial direction.

The internal spindle is connected to the screw, and the screw is pivotally connected to the core former, which has a degree of freedom relative to the body of the working element in the direction of its axis.

The rotation and axial vibration of the internal spindle is transmitted to the propeller auger, and the puncher performs axial oscillations on the rod, which, in the place of attachment to it of the puncher, has a square cross-section, allowing axial displacements transmitted to the puncher from the screw and preventing rotation of the puncher.

Concrete from the hopper is fed to the auger and compacted by the working body. During the extrusion of hardening material, the extruder moves over the formwork due to pushing away from the compacted hardening material.

Thus, on the production line, building structures 1 are made, for example, hollow slabs with the formation of the required number of voids of the required shape in the finished product, as well as extended building structures, for example beams 20, including I-beams 21.

They can use the core former 9 with a thickness of lesser thickness and formable building structure 1.

On the production line, building structures 1 are made in the form of hollow plates 15 mainly with round 16 or oval 17 in the cross section of the voids, for which use is made of a round or oval hollow core 9.

Or, on a production line (not shown), building structures are made in the form of hollow plates 15 with voids in cross section in the form of a rectangle 18, triangle 19 or a star with rounded corners (not shown in the drawings) for which they use a core former having a cross section a rectangle, a triangle or a star with rounded corners (not shown in the drawings).

Or they can use a core former with a thickness not smaller than that of a formable building structure 1 and then extensive building structures are made on the production line, for example beams 20, including I-beams 21.

Also when implementing the method, the extruder can operate as follows. From the motor mounted on the extruder, rotation is transmitted to it via the device for rotating the internal spindle.

The external spindle is also set in motion by means of a device transmitting the rotation from the internal external, thus ensuring their free movement relative to each other in the axial direction, and using a device for transmitting axial vibration to the external spindle, it is also given a reciprocating motion.

The outer spindle transmits rotation and axial vibration to the auger, and the auger is pivotally connected to the core former, which has a degree of freedom relative to the body of the working element in the direction of its axis and produces reciprocating movements.

Concrete from the bunker is fed to the auger and compacted by the working body with the formation of the required number of voids in the finished product.

Concrete from the hopper is fed to the auger and compacted by the working body. During the extrusion of hardening material, the extruder moves over the formwork due to pushing away from the compacted hardening material.

Thus, on the production line are made building structures 1, for example,

- 3 009137 hollow slabs with the formation of the required number of voids of the required shape in the finished product, as well as extensive building structures, for example, beams 20, including I-beams 21.

They can use the core former 9 with a thickness that is less than the thickness of the moldable building structure 1.

On the production line, building structures 1 are made in the form of hollow plates 15 mainly with round 16 or oval 17 in the cross section of the voids, for which use is made of a round or oval hollow core 9.

Or, on a production line (not shown), building structures are made in the form of hollow plates 15 with voids in cross section in the form of a rectangle 18, triangle 19 or a star with rounded corners (not shown in the drawings) for which they use a core former having a cross section a rectangle, a triangle or a star with rounded corners (not shown in the drawings).

Or they can use a core former with a thickness not less than the thickness of the formable building structure 1, and then extensive building structures, for example beams 20, including I-beams 21, are made on the production line.

By producing building structures in the manner described, high quality molded reinforced concrete products is achieved, the density and strength of concrete in the product is increased by increasing plasticity and reducing the frictional properties of the concrete mix directly at the interfaces of the concrete mix and the working surfaces of the extruder spiral vanes.

Claims (5)

CLAIM 1. A method of manufacturing building structures, mainly hollow core slabs, by extrusion on a production line including formwork with a pallet and an extruder with a hopper for hardening material and a working body, characterized in that it provides for the installation of fittings on the formwork pallet, loading of hardening material into the hopper and feeding it on the formwork pallet with compaction and molding, moreover, for the compaction and molding of hardening material, the working body of the extruder, consisting of at least one working of the element containing the housing, the hollow forging element installed coaxially with the guide rod, the hollow blade screw, the external and internal spindles, one of the spindles being rotated, and axial vibration is transmitted to the second spindle, while the rotatable spindle transmits rotation to the other by means of a device that provides free the movement of the spindles relative to each other in the axial direction, and the spindle to which the axial vibration is transmitted, as well as rotation, is rigidly connected to the screw, and the screw with a free end pivotally connected to a core former mounted on a rod with the possibility of only axial vibrations. 2. The method according to claim 1, characterized in that the external spindle is rotated, and vibration is transmitted to the internal, and rotation is transmitted from the external spindle to the internal by means of a device, for example, in the form of a tooth on one spindle, entering an axially elongated groove of another spindle or by means of a key installed in axially elongated grooves of the spindles, and the screw is rigidly attached to the internal spindle, or rotate the internal spindle, and vibration is transmitted to the external, and rotation is transmitted from the internal spindle external by means of a device, for example, in the form of a tooth on one spindle, entering the axially elongated groove of the other spindle, or by means of a key installed in the axially elongated grooves of the spindles, and the screw is rigidly attached to the external spindle. 3. The method according to claim 1, characterized in that on the production line building structures are made in the form of hollow slabs mainly with round, oval or in the form of a rectangle with rounded corners in the cross section of the voids, for which round, oval or in the form of a rectangle with rounded corners in the cross section of the core, the thickness of which is less than the thickness of the molded building structure, or on the production line make extended building structures, for example double level beams, while using a hollow core with a thickness not less than the thickness of the molded building structure. 4. The method according to claim 1, characterized in that during the extrusion of the hardening material, the extruder moves above the formwork due to repulsion from the compacted hardening material, and heavy concrete is used as the hardening material, using the working body of the extruder, consisting of at least two working elements, and the screw blade of each adjacent working element has an opposite direction of rotation, and pre-stressed building structures are made on the production line, for which by extrusion of hardened material, the reinforcement is tensed. 5. Building structure, characterized in that it is made by the method according to any one of claims 1 to 4.