KR102644499B1 - Method for compacting mortar with fiber reinforcement - Google Patents

Abstract

The present invention relates to a method of compacting a mortar containing a fiber reinforcement material made of twisted single fibers and metal yarns. More specifically, the fiber reinforcement material formed by twisting single fibers and metal yarns is moved to a certain depth from the surface forming the wall to form a mortar. Compaction of mortar containing fiber reinforcement made of short fibers and metal threads twisted to form a surface like a regular mortar surface by preventing it from protruding when forming a wall, making it easy to remove air bubbles, improving convenience, and improving the quality of the cured wall. The present invention relates to a method for compacting a mortar containing fiber reinforcement made of twisted single fibers and metal yarns, in which the reinforcement made of short fibers and metal yarns twisted in the space between the formwork made of metal to which electromagnets are attached is used to compact concrete. When mixed and filled with mortar, the vibrating device is closely attached to the metal form to transmit vibration to the mortar, and a solenoid device is installed between the form and the vibrating device to transmit vibration to remove air bubbles in the concrete mortar. there is.

Description

Method for compacting mortar with fiber reinforcement}

The present invention relates to a method of compacting a mortar containing a fiber reinforcement material made of twisted single fibers and metal yarns. More specifically, the fiber reinforcement material formed by twisting single fibers and metal yarns is moved to a certain depth from the surface forming the wall to form a mortar. Compaction of mortar containing fiber reinforcement made of short fibers and metal threads twisted to form a surface like a regular mortar surface by preventing it from protruding when forming a wall, making it easy to remove air bubbles, improving convenience, and improving the quality of the cured wall. It's about method.

In general, the technology of making various blocks or moldings using concrete mortar has already been widely used in the construction and civil engineering fields for a long time. These concrete moldings are completed by filling a mold of the same shape with concrete mortar and then curing it for a certain period of time.

At this time, if the air bubbles in the concrete mortar filled in the form are not completely removed, they become a factor that impedes the durability of the molded product. Therefore, air bubbles remaining in the concrete mortar must be released to the outside and removed to obtain a high-quality molded product.

In addition, since reinforcing bars are inserted inside the form to reinforce strength, it is understandable that a high-quality molded product can be obtained only when every corner of the form is well filled without the concrete mortar being interfered with by the inserted reinforcing bars.

Meanwhile, in order to improve the tensile strength of concrete mortar, fiber reinforcement made of short fibers is used mixed with concrete mortar.

To solve this problem, it is effective to apply vibration to the concrete mortar filled in the form and shake it. For example, when the depth of the concrete mortar filled in the form is not deep, a vibrator is inserted directly into the concrete mortar and vibration is transmitted to remove air bubbles inside the concrete mortar. However, to form a wall of a certain thickness, concrete mortar is poured between the forms. After processing, the vibrator cannot be used, so workers remove air bubbles by tapping the form with a rubber bar or rubber mallet.

This method of removing air bubbles has limitations in transmitting vibration because the worker must tap with force, and it also causes high fatigue and musculoskeletal disorders. As shown in FIG. 1a of the attached drawing, the conventional work method for removing air bubbles did not completely remove the air bubbles and created bubbles, which caused a decrease in strength. In addition, as shown in FIG. 1b of the attached drawing, the reinforcement material was exposed to the surface. This impairs the aesthetics, and when you touch the surface, it feels rough due to the reinforcing material. When paint is applied to this surface, there is also a problem that the paint easily falls off due to the reinforcing material.

The present invention, which was developed in consideration of these conventional problems, prevents surface exposure of the reinforcement when forming a wall with mortar by moving the fiber reinforcement formed by twisting single fibers and metal threads to a certain depth from the surface forming the wall, thereby creating a mortar mixed with reinforcement. The aim is to provide a compaction method for concrete mortar containing fiber reinforcement made of short fibers and metal threads twisted to form an elegant surface like a regular mortar surface.

In addition, it has a beautiful surface that prevents the paint from peeling off for a long time even after paint work, and is made of short fibers and metal threads that are effective in improving the quality of concrete mortar after curing by making it easy to remove air bubbles. The aim is to provide a method for compacting concrete mortar containing fiber reinforcement.

The object of the present invention described above is a method of compacting a mortar containing fiber reinforcement made of twisted single fibers and metal threads, wherein the reinforcing material made of twisted single fibers and metal threads is mixed with concrete mortar in the space between the formwork made of metal materials to which magnets are attached. In the filled state, the vibrating device is closely attached to a metal form to which a magnet attaches and the vibration is transmitted to the mortar. A solenoid device is installed between the form and the vibrating device, so that one side of the vibrating device is held by the worker and the other side is held by the solenoid device. This is achieved by compacting a mortar containing a fiber reinforcement made of twisted single fibers and metal threads, which is fixed and transmits vibration to remove air bubbles.

A fiber made of twisted single fibers and metal threads, characterized in that when the metal form to which the magnet is attached is vibrated with the vibrating device, the fiber reinforcement material made of twisted single fibers and metal threads moves from the surface to the center at a certain depth and is not exposed to the surface. This is achieved by compacting the mortar containing reinforcement.

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The present invention prevents surface exposure of the reinforcement material when forming a wall with mortar by moving the fiber reinforcement material formed by twisting single fibers and metal threads to a certain depth from the surface forming the wall, thereby converting the surface of the mortar mixed with the reinforcement material to the surface of a general mortar. The aim is to provide a method of compacting concrete mortar containing fiber reinforcement made of short fibers and metal threads twisted to form an elegant shape as shown.

In addition, it has a beautiful surface that prevents the paint from peeling off for a long time even after paint work, and is made of short fibers and metal threads that are effective in improving the quality of concrete mortar after curing by making it easy to remove air bubbles. The aim is to provide a method for compacting concrete mortar containing fiber reinforcement.

Figure 1a is a surface photograph of a wall in which air bubbles in the concrete mortar poured by tapping with a conventional rubber mallet or rubber bar were removed.
Figure 1b is a surface photograph of a wall cured by mixing reinforcing material made by twisting short fibers and metal threads into a conventional concrete mortar and mixing it with the concrete mortar.
Figure 2a is a front example showing a method of compacting concrete mortar containing fiber reinforcement when forming a wall with a thickness of 30 mm or less to which the technology of the present invention is applied.
Figure 2b is a side view showing a compaction method of concrete mortar containing fiber reinforcement when forming a wall with a thickness of 30 mm or less to which the technology of the present invention is applied.
Figure 3a is a front example showing another compaction method of concrete mortar containing fiber reinforcement when forming a wall with a thickness of 30 mm or less when the formwork is non-metallic.
Figure 3b is a side view showing another compaction method of concrete mortar containing fiber reinforcement when forming a wall with a thickness of 30 mm or less when the formwork is non-metallic.
Figure 4a is a surface photograph of a wall cured with concrete mortar in which air bubbles were removed by the compaction method of the present invention.
Figure 4b is a cross-sectional photograph of a wall cured with concrete mortar in which air bubbles were removed by the compaction method of the present invention.

Hereinafter, a preferred embodiment of the present invention will be described in detail based on the attached drawings.

The attached drawing, Figure 2a, is a frontal illustration showing a compaction method of concrete mortar containing fiber reinforcement when forming a wall with a thickness of 30 mm or less to which the technology of the present invention is applied, and Figure 2b is a front view showing a method of compacting a concrete mortar containing fiber reinforcement with a thickness of 30 mm or less to which the technology of the present invention is applied. This is a side illustration showing a method of compacting concrete mortar containing fiber reinforcement when forming a wall. The compaction method of the present invention according to this is a method of compacting concrete mortar containing fiber reinforcement made of short fibers and metal threads twisted,
The form is made of a metal form (100) to which a magnet is attached, and a solenoid device (500) is installed between the vibrating device (400) and the metal form (100), and the solenoid device (500) is attached to the metal form (100). Connected, the vibration of the vibration device 400 is transmitted to the metal formwork 100 and the concrete mortar 300 containing the fiber reinforcement through the solenoid device 500, thereby forming the concrete mortar 300 containing the fiber reinforcement. It is a compaction method of concrete mortar containing fiber reinforcement, which is designed to remove air bubbles within the mortar, and is characterized in that the fiber reinforcement moves from the surface to the center at a certain depth and is not exposed to the surface.

Here, when the mold 100 is made of a metal material as shown in FIGS. 2A and 2B, the metal mold 100 is preferably made of a metal to which a magnet is attached.

The thickness of the form 100 is within 2 to 3 mm. The reason is that when using a metallic formwork 100 of 2 mm or less, there is a risk of deformation of the form due to vibration, and a formwork with a thickness of 3 mm or more is heavy and has a problem of reduced vibration transmission ability.

Meanwhile, the concrete mortar 300 used in the present invention is made by mixing mortar powder mixed with cement and sand, powdered admixture, and filler. Prepare mortar powder mixed with cement and sand. At this time, the cement and sand are mixed at a weight ratio of 1:1 or 3:1, and aggregate or lightweight aggregate can also be mixed.

The admixture consists of a water reducing agent, an antifoaming agent, and a shrinkage reducing agent. Assuming that the admixture is 100% by weight, 0.2 to 1.0% by weight of the water reducing agent, which is mainly intended to improve the workability of concrete by dispersing the cement powder, is added by friction during mixing. Use a mixture of 0.4-2.0% by weight of anti-foaming agent, which is effective in suppressing air bubbles, and 0.5-2.0% by weight of shrinkage reducing agent.

When the above admixture is 100% by weight, if less than 0.2% by weight of the high-performance water reducer is used, there is a problem of increasing the water/binder ratio due to the increase in the amount of water mixed, and if the high-performance water reducer is used more than 1.0% by weight, there is a problem of material separation. Because there is.

On the other hand, when the admixture is 100% by weight, if the antifoamer is used in an amount of 0.4% by weight or less, the effect of removing closed cells is reduced, and if the antifoamer is used in an amount of 2.0% by weight or more, agglomeration occurs.

When the above admixture is 100% by weight, if the shrinkage reducer is used at less than 0.5% by weight, there is a problem of cracks occurring due to self-contraction. If the shrinkage reducer is used at more than 2.0% by weight, mechanical performance such as compressive strength and tensile strength may be affected. This is because there is a problem of decline.

The filler has a structure composed of a vitreous hollow microstructure, a mixed yarn formed by twisting synthetic fibers and metal yarns, or a mixture thereof. The glassy hollow microstructure is made by mixing SiO ₂ and CaO and has a hollow structure.

The manufacture of the vitreous hollow microspheres involves mixing silica (SiO ₂ ), the main raw material, and CaO, SiO ₂ , which are secondary raw materials, and melting them at a high temperature, then rapidly cooling them with cooling water, and forming a high powder form by natural crushing and mechanical crushing. It is made with

Then, by foaming the fine powder with high-temperature vapor pressure and sulfur dioxide gas to form spherical particles, and applying fumed silica to the surface to prevent sticking, porous glassy hollow microspheres are created.

These vitreous hollow microspheres have advantages such as weight reduction, improved fluidity, resistance to shrinkage and bending, insulation, chemical resistance, and low water absorption. In particular, due to the form of the hollow structure surrounding the air and SiO ₂ filled inside the thin film, It has the advantage of excellent insulation performance.

The concrete mortar 300 was cured using the compaction method as shown in FIGS. 2A and 2B of the attached drawings, and the surface was examined. As shown in FIG. 4A of the attached drawing, it was formed by pounding with a rubber bar, etc. It was found that the reinforcement material visible on the concrete mortar surface represented an invisible surface.

Meanwhile, as the vibration of the vibrating device 400 is transmitted to the poured concrete mortar 300, the fiber reinforcement shown in Figure 4b of the attached drawing is moved to a certain depth from the surface, preventing surface exposure of the reinforcement when forming a wall with mortar. The surface of the mortar mixed with reinforcing materials is formed beautifully as shown in Figure 4a.

On the other hand, in the case of metal or wood and synthetic resin that do not attract magnets, as shown in Figures 3a to 3b of the attached drawings, a fiber reinforcement made of single fibers and metal threads twisted in the space 200 between the form 100a and the form 100a is used in concrete. It is mixed with mortar and filled, and a space is provided on the outside of the formwork (100a) on the inside where the horizontal rail 610 and the vertical rail 620 intersect, and the horizontal rail 610 and the vertical rail 620 intersect. A solenoid device 500 is fixedly installed in the center to transmit vibration to remove air bubbles.

The reason for using the solenoid device 500 in the present invention is that when power is supplied, it becomes an electromagnet that generates magnetic force, and when the power is turned off, the magnetic force disappears, thereby canceling the fixing force of the vibration device 400.

Therefore, the reason for using the metal formwork 100 or installing the metal rail on the wooden formwork 100a is to fix the vibration device 400 using the solenoid device 500, and also to fix the vibration device 400 to the formwork. This is to provide the convenience of transmitting vibration by simply and easily moving the location.

According to the present invention, when a metal form attached to a magnet is vibrated using the vibrating device, the fiber reinforcement formed by twisting single fibers and metal threads moves from the surface to a certain depth toward the center, thereby preventing surface exposure of the reinforcement when forming a wall with mortar. This has the effect of forming the surface of the mortar mixed with reinforcing materials as beautifully as the surface of regular mortar. In addition, the beautiful surface prevents the paint from peeling off for a long period of time even after painting, and it is convenient to remove air bubbles and remove the air bubbles. Removal has the effect of improving the quality of concrete mortar after curing.

100: formwork
200: space
300: Concrete mortar
400: Vibration device
500: Solenoid device

Claims (3)

In the compaction method of concrete mortar containing fiber reinforcement made of twisted short fibers and metal threads,
The form is made of a metal form to which a magnet is attached, and a solenoid device is installed between the vibrating device and the metal form. The solenoid device is connected to the metal form, and the vibration of the vibrating device passes through the solenoid device to the metal form and the above metal form. It is delivered to concrete mortar containing fiber reinforcement to remove air bubbles in the concrete mortar containing fiber reinforcement. In addition, the fiber is characterized in that the fiber reinforcement moves from the surface to the center at a certain depth and is not exposed to the surface. Compaction method of concrete mortar containing reinforcement. delete delete