SU939213A1 - Installation for moulding three-dimensional blocks - Google Patents

Description

one

The invention relates to construction and is intended for the manufacture of bulk units.

A known apparatus for forming bulk blocks, comprising a base with outer boards and a core made in the form of side shields and corner wedge elements connected by a toggle link with the central post 1.

The disadvantage of the installation is the presence of a large number of hinged joints, which leads in the process of operation to the violation of the size of the manufactured products and the rapid deterioration of the equipment.

Closest to the present invention is an installation for forming bulk blocks comprising a frame with external boards and a core with a ceiling shield, inner formwork panels and corner elements 2.

A disadvantage of the known installation is that the quality of the surfaces of the manufactured products in the places of interface with the corner elements deteriorates during the operation of the installation, since the gaps between the boards of the internal formwork

and angular elements increase. In addition, an increase in clearances leads to jamming of the corner elements in the guide grooves, since cement milk flows there, and this in turn makes stripping difficult.

The purpose of the invention is to simplify the stripping and improve the quality of the product.

This goal is achieved by the fact that in an apparatus for forming volumetric blocks comprising a frame with outer sides and

10 core with a ceiling panel, inner formwork panels and corner elements associated with the latter, each corner element is made in the form of an eccentric shaft mounted on the base of the core, and communication with inner formwork panels is

15 in the form of flexible connections attached by one ends to the upper and lower parts of the eccentric shaft at the places of greater and smaller radii of curvature of the lateral surface, and by the other ends to the inner shields

20 of the formwork, with blocks inside the core on its uprights, through which flexible connections are passed, connected to the eccentric shaft in places of a smaller radius of curvature of its side surface.

FIG. 1 shows the proposed installation, a general view; in fig. 2 - internal formwork; in fig. 3 is a section A-A in FIG. 2, in FIG. 4 is a section BB in FIG. 2; HJ FIG. 5, node I in FIG. 3 (in two positions); in fig. 6 - the same, in a perspective view; in fig. 7 - node II in FIG. four.

The installation comprises a frame 1 with hinged external boards 2, a core 3 mounted on a vibrating plate 4. The core 3 is a frame consisting of a base 5, pillars 6, hollow shields 7 of the inner formwork and a hollow ceiling shield 8. In places of junction Shields 7 on the base 5 are installed angular elements in the form of eccentric shafts 9, shanks 10 passing through the base 5 of the core 3.

On the foundation of the installation coaxially with the shanks 10 are located drives 11 of the rotation of eccentric shafts 9. As a drive 1 1 of rotation, for example, an electric motor with a reducer can be used, on the output shaft of which there is a slot under the shank 10 of the eccentric shaft 9.

The outlines of the side surface of each eccentric shaft 9 in contact with the shields 7 are made in the form of an Archimedes spiral with a large R and a smaller r radius 12 and 13 of curvature. Each eccentric shaft 9 is connected by flexible couplings 14 and 15 to shields 7 in the upper and lower parts. The links 14 are fixed to the eccentric shaft 9 at the locations of a larger radius 12, and the bonds 15 are smaller radius 13 and are wrapped around the blocks 16 fixed on the uprights 6 of the core 3. The ceiling shield 8 and the base 5 of the core 3 are made with pins 17, and the horizontal faces of the shields 7 are made with corresponding slots 18 under the pins 7.

The installation works as follows.

Before concreting, the sides 2 are exposed, for example, by a hydraulic actuator (conventionally not shown). The outer boards 2, inner formwork boards 7, ceiling shield 8 and eccentric shafts 9 are cleaned and lubricated. Eccentric shafts 9 are in contact, end with end faces of shields 7, and connections 14 and 15 are in a tensioned state. Further, actuators 11 of eccentric shafts 9 are turned on (inclusion can be carried out in any sequence). When the eccentric shafts 9 are rotated clockwise, their lines of contact with the end faces of the shields 7 move along the lateral surface of the eccentric shafts 9, the radius of curvature of which to the touch test increases as they turn, as the outlines of the lateral surface of each shaft 9 are in the form of an Archimedes spiral. When this occurs, the shields 7 move from the core 3. When the shields 7 are moved, the pins 17 of the ceiling shield 8 and the base 5

the core 3 is moved up to the stop to the slots x 18 of the horizontal faces of the shields 7, and the connections 14 and 15 and come to a free undefined position. After that, turn off the actuator 11, while the eccentric shafts 9 and shields 7 in position a (Fig. 3).

For example, the core 3 is mounted on the inner formwork with a crane and the outer sides 2 are brought into a vertical position, for example, by a hydraulic actuator (not shown conventionally). Next, a concrete paver (not shown) located above the installation, serves the concrete mix into the molding cavity formed by the outer boards 2 and the shields 7. At the same time, the vibratory plate is switched on 4. The concrete mix is compacted.

After concreting, in the cavities of the shields 7 and the ceiling shield 8, coolant is supplied and the product is heat-treated. At the end of the heat treatment, the product is dismantled. For this, the outer boards 2 are exposed and diverted from the product. The actuators 11 are turned on, the eccentric shafts 9 rotate counterclockwise, separating from the concrete in the corners of the product and the shields 7. With further rotation of the shafts 9, the gap between them and the shields 7 increases, and the flexible connections 14 and 15 tighten and move the shields 7 to the core 3, separating them from the product (Fig. 36). The pins 17 are moved in the slot x 18 up to the stop, and the shields 7 come into contact with the shafts 9. The drives 11 are turned off. Next, the product is removed with a crane and the process is repeated.

The proposed installation compared to the known has greater reliability during demoulding and provides for obtaining products of better quality, reducing the labor costs for maintenance and reducing the cost of production by 0.4-0.5 rubles / m.

Claims (2)

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