KR200209048Y1 - A composite shaped Block having with multiple section coefficient - Google Patents

Abstract

The present invention relates to a composite molding block having a multi-section coefficient to prevent soil disintegration, comprising: a composite molding block comprising a reinforcing member and ribs formed by pressing waste material to the outside of the reinforcing member; The reinforcing member 3 includes a plurality of central reinforcing members 10 installed in the vertical central portion 11, a plurality of horizontal reinforcing members 30 disposed on the vertical upper and lower portions 31, and a middle between the vertical central portion and the upper and lower portions. It is composed of a plurality of intermediate reinforcing members 20 of a relatively lower height than the central reinforcing member and the horizontal reinforcing member is built in the portion 21.

Description

A composite shaped block having with multiple section coefficient

The present invention has a simple beam-type complex molding block having a multi-section coefficient to prevent soil disintegration in which the reinforcing members having different numbers, heights, or thicknesses are installed in each part to have a multi-section coefficient (hereinafter, soil barrier) It includes a product in which a reinforcing member is embedded and ribs are formed, such as a plate, a soundproof board, a protection board or a formwork.).

The conventional simple block-type block using wood, the molding block using steel, the composite molding block in which the reinforcing member 3 having a uniform cross-sectional coefficient of various shapes in the waste material is shown in FIGS. 1 and 2a to 2c. As shown, it has the same single section coefficient with respect to the entire length of the member where the bending moment occurs without considering the required bending moment.

Such a conventional composite block having a single cross-sectional coefficient (hereinafter, includes a product in which a reinforcing member is formed and a rib is formed, such as an earthen board, a soundproofing plate, a protective plate, or a formwork, etc.) (3) ) Has the same cross-sectional coefficient throughout the composite block.

However, the conventional composite block 1 formed to have the same cross-sectional modulus even though the bending moment of the transverse center portion is relatively large compared to the bending moment of both ends is unnecessarily large on both sides of the transverse side which receive a relatively small bending moment. There was an unreasonable point of installing a reinforcing member having a section modulus.

In addition, the bending moment of the transverse side is relatively much larger than the bending moment generated at both ends. By doing the same, there was a problem of causing unnecessary resource waste and raising manufacturing costs due to unnecessary burdens such as raw materials, raw materials, power, labor costs, etc. required to manufacture the composite molding block 1.

Furthermore, since the conventional composite block 1 having a single section coefficient is larger in volume and weight than the generated bending moment, the builder who constructs the composite block in the field is transported or moved for construction of the composite block. The reality is that there have been significant difficulties in assembly.

In addition, after the construction, due to some unnecessary self-load of the composite block having a single section coefficient, the composite block installed at the bottom may be ruptured or dislodged by applying a bending moment and shear force to the composite block installed at the bottom, which may cause a risk. It can be.

Therefore, the object of the present invention is to support the composite moment while efficiently supporting the bending moment received by the composite molding block (hereinafter, including a product formed by forming a rib with a reinforcing member such as a retaining plate, a soundproof plate, a protective plate or a formwork, etc.) It is to provide a composite molding block having a multi-section coefficient that reduces the manufacturing cost, such as the raw material cost to manufacture the molding block.

It is another object of the present invention to provide a composite block having a multi-section coefficient that minimizes volume and weight so as to satisfy the bending moment required when constructing a composite block in the field, and to facilitate transportation, movement, or assembly.

Another object of the present invention is to provide a composite molding block having a multi-section coefficient to prevent the risk of rupture of the composite molding block installed at the bottom after construction.

1 is a perspective view of a conventional composite block having a single section coefficient.

Figure 2a is a cross-sectional view taken along the line A-A 'of the conventional composite block having a single section coefficient.

Figure 2b is a cross-sectional view of B-B 'of the conventional composite block having a single section coefficient.

Figure 2c is a cross-sectional view of C-C 'of the conventional composite block having a single section coefficient.

3 is a perspective view of a composite molding block having a multi-section coefficient according to the present invention.

4A is a cross-sectional view taken along the line A-A 'of a composite block having a multi-section coefficient according to the present invention.

Figure 4b is a cross-sectional view of B-B 'of the composite block having a multi-section coefficient according to the present invention.

Figure 4c is a cross-sectional view of the C-C 'of the composite block having a multi-section coefficient in accordance with the present invention.

Figure 5 is a graph of the relationship between the composite block and the bending moment having a multi-section coefficient according to the present invention.

[Explanation of symbols on the main parts of the drawings]

1: Composite Molding Block 2: Waste Materials

3: reinforcing member 4: rib

10: center reinforcing member 11: longitudinal center

20: intermediate reinforcing member 21: longitudinal middle portion

30: horizontal reinforcing member 31: vertical side upper and lower

40: center overlap reinforcement member

In the composite molded block having a multi-sectional coefficient of the present invention for achieving the above object is a composite molded block having a reinforcing member, and ribs are formed by pressing the waste material to surround the outside of the reinforcing member; The reinforcing member 3 includes a plurality of central reinforcing members 10 installed in the vertical central portion 11, a plurality of horizontal reinforcing members 30 disposed on the vertical upper and lower portions 31, and a middle between the vertical central portion and the upper and lower portions. The basic technical idea of the present invention is that the internal reinforcing part 21 is composed of a plurality of intermediate reinforcing members 20 having a lower height h ′ than the central reinforcing member and the horizontal reinforcing member.

The composite molding block 1 having the multi-section coefficient includes a different quantity, height h 'or thickness of each reinforcing member constituting the reinforcing member, and is formed by pressing waste material to the outside of the reinforcing member. It includes the quantity, height (h) or thickness of the rib to be different.

Hereinafter, the present invention will be described in more detail with reference to exemplary embodiments shown in the accompanying drawings.

3 and 4a to 4c is a perspective view and a cross-sectional view of a composite block having a multi-section coefficient according to the present invention, Figure 5 shows a bending moment of a composite block having a multi-section coefficient according to the present invention It is a graph.

In the embodiment of the present invention, as shown in Figure 3, the composite molded block 1 having a multi-section coefficient according to the present invention is a plurality of central reinforcing members (10) in the longitudinal longitudinal center portion 11, the longitudinal side The configuration includes a plurality of horizontal reinforcing members 30 disposed on the upper and lower portions 31 and a plurality of intermediate reinforcing members 20 installed in the intermediate portion 21 running from the upper and lower portions 31 on the vertical side toward the center portion 11. It is to implement the basic technical idea of the present invention in that it has elements.

The composite molded block 1 having the multi-section coefficient according to the present invention is characterized in that the bending moment is increased by increasing the cross-sectional coefficient as the position (center of the vertical side, the center of the horizontal side) which receives a large bending moment. .

There are various ways to achieve this purpose depending on the city factory. However, the following four methods are used as principles, and the other methods are applied in combination of four principles to satisfy the required section modulus. will be.

First, in the composite molding block, the required section modulus is formed by increasing the number, thickness, or height (h) of the rib by using waste materials for the position where the large section modulus is required (mainly in the middle of the transverse side and the center of the longitudinal side). To meet.

Second, for the position where a large cross-sectional coefficient is required in the composite molding block, increase the number or height (h´) or thickness of the reinforcement member in the rib formed from the waste material, adjust the position of the reinforcement member, or The reinforcement is overlapped to increase the section modulus.

Third, the cross-sectional coefficient is increased by deforming the shape of the reinforcing member for the position where a large cross-sectional coefficient is required in the composite molded block.

Fourth, the weight and volume of the composite block are minimized to the extent that the bending moments required for the composite block are met.

Such a composite block having a multi-section coefficient according to the present invention can be various embodiments of adjusting the number and position of the reinforcing member by combining the four principles according to the city factory, the step coefficient is increased step by step Representative embodiments are as follows.

As shown in FIGS. 3 and 4A to 4C, two thin horizontal reinforcing members 30 respectively installed in the upper and lower portions 31 on the vertical side and a thick center reinforcing member 10 installed in the central portion 11 on the vertical side are provided. Represents a composite molded block having a multi-section coefficient composed of one and a plurality of intermediate reinforcing members 20 built in the horizontal central portion b with respect to the longitudinal middle portion 21 and having a length smaller than the horizontal and central reinforcing members. will be.

The reinforcing members may be overlapped with a plurality of reinforcing members to increase the bending moment, or by inserting a central overlap reinforcing member 40 that supplements the central reinforcing member 10 with a metal or an iron core to the central reinforcing member. The reinforcing member and the rib are preferably increased in quantity, thickness, and height toward the central portion of the longitudinal side and toward the central portion of the horizontal side.

The present invention, as shown in Figure 5, even when viewed from the horizontal side the relationship between the bending moment and the length of the composite molding block is (M: bending moment, W: earth pressure, L: transverse length of the composite block, X: arbitrary length of the composite block horizontal side), which is a parabola that is a graph of the ideal bending moment with respect to the transverse center part (c). It appears in the form of a step function that converges to.

Since the dotted line, which is a bending moment graph of a molded block having a single section coefficient, has a constant value, there is an unreasonable point of maintaining the maximum value even at both ends of the transverse side (parts a to b except for a small bending moment). The graph of a composite block having a multi-section coefficient according to the present invention has a discontinuous value close to a parabola, which is an ideal bending moment graph.

That is, since the bending moment at the center of the horizontal side has a maximum value, the cross-sectional coefficient is maximized at the center of the horizontal block of the composite block and decreases as it progresses through the middle of the horizontal side (excluding b to c) to both ends of the horizontal side. .

Therefore, as shown in the graph, the area difference (P and P ') on the coordinate axis between the conventional constant bending moment graph and the bending moment graph having a discontinuous value converging to the parabola of the present invention was an inefficient use of resources.

In addition, it can be seen from the longitudinal side that the central portion is a parabolic shape having a maximum value, and as the position in the composite molding block moves from the upper and lower portions 31 to the central portion 11, the required bending moment increases and the maximum at the central portion. Therefore, the upper and lower portions 31 are to have a maximum value at the center by increasing the smaller the cross-sectional coefficient and moving toward the central portion (11).

Thus, the present invention is to increase the cross-sectional coefficient at the required position on the basis of the bending moment of the upper and lower portions 31 by adjusting the number, height, position or thickness of the reinforcing member according to the bending moment of the factory.

In addition, it is preferable to use a method of adjusting the number and thickness of the ribs 4 formed by pressing the waste material to the outside of the reinforcing member by pressing the reinforcing member, and increasing the cross-sectional coefficient of each reinforcing member of the reinforcing member. It is also possible to increase the cross-sectional coefficient by installing the same or different cross-sectional shape.

Therefore, the present invention can efficiently reduce resources, thereby preventing unnecessary waste of resources, and reducing manufacturing costs by reducing the costs of raw materials and the like for manufacturing the composite molded block.

Although the present invention has been described with reference to the above embodiments, it is not necessarily limited thereto, and various modifications may be made without departing from the scope and spirit of the present invention.

As described above, the composite molded block having a multi-sectional coefficient according to the present invention prevents unnecessary waste of resources by introducing a reinforcing member to effectively support the bending moment required according to the position, and the raw materials required to manufacture the composite molded block. The cost of manufacturing is reduced by reducing the cost.

In addition, the composite molded block having a multi-section coefficient according to the present invention is manufactured in consideration of the volume and weight of the composite molded block in accordance with the construction site to transport or move to the installer while meeting the bending moment required when constructing the composite molded block in the field. Or to facilitate assembly.

In addition, the composite molding block having a multi-section coefficient according to the present invention has the effect of preventing the risk of rupture by minimizing the bending moment and shear force transmitted due to its own load on the composite molding block installed at the bottom after construction.

Claims (9)

In the composite molding block having a reinforcing member and a rib (Rib) is formed by pressing the waste material to surround the outside of the reinforcing member; The reinforcing member A plurality of central reinforcing members 10 installed in the longitudinal central portion 11; A plurality of horizontal reinforcing members 30 disposed on the vertical side upper and lower portions 31, Composite molding having a multi-section coefficient, characterized in that it comprises a plurality of intermediate reinforcing member 20 is lower than the center reinforcing member and the horizontal reinforcing member in the intermediate portion 21 between the longitudinal center and the upper and lower parts block. The method of claim 1; The quantity of each of the reinforcing members constituting the reinforcing member (10, 30, 20) is a composite molded block having a multi-section coefficient, characterized in that increases toward the center of the horizontal side, toward the center of the vertical side. The method of claim 1; The thickness of each of the reinforcing members constituting the reinforcing member (10, 30, 20) is a composite molded block having a multi-section coefficient, characterized in that increases toward the center of the horizontal side, toward the center of the vertical side. The method of claim 1; The height of each reinforcing member constituting the reinforcing member (h ') is a multi-component molded block having a multi-sectional coefficient characterized in that the number increases toward the center of the horizontal side, toward the center. The method of claim 1; The composite molded block having a multi-section coefficient, characterized in that the cross-sectional shape of each of the reinforcing members constituting the reinforcing member (10, 30, 20) is different depending on the position. The method of claim 1; Complex molding block having a multi-section coefficient, characterized in that the reinforcement is added to the central reinforcing center reinforcement member. The method of any one of claims 1 to 6; The number of the ribs (Rib) composite molded block having a multi-section coefficient, characterized in that increases toward the center of the horizontal side, toward the center of the vertical side. The method of any one of claims 1 to 6; The thickness of the rib (Rib) composite molded block having a multi-section coefficient, characterized in that increases toward the center of the horizontal side, toward the center of the vertical side. The method of any one of claims 1 to 6; The height of the rib (Rib) is a composite molded block having a multi-section coefficient, characterized in that increases toward the center of the horizontal side, toward the center of the vertical side.