KR20210033212A - Moire phenomenon analysis method of window filter and analysis device there of - Google Patents

Abstract

The present invention provides a method for analyzing moire phenomenon of a filter for window that mesh layers having different periodic patterns and a fiber layer provided on mesh layers, and a moire phenomenon occurs. The method comprises: a first calculation step of transforming the mesh layers and the fiber layer having different periodic patterns into first and second matrices, respectively, and calculating a first summation having a moire pattern in which a moire phenomenon occurs based on the result of summing the transformed first and second matrices; a second calculation step of converting a pattern layer having an arbitrary pattern into a third matrix, and calculating a second summing matrix based on a result of summing with the first summing matrix; and a determination step of determining whether the moire phenomenon occurs by comparing the first and second summation matrices.

Description

Moire phenomenon analysis method of window filter and analysis device there of}

The present invention relates to a moire phenomenon analysis method and an analysis apparatus, and more particularly, to a moire phenomenon analysis method of a window filter that predicts a moire phenomenon that occurs due to overlapping different periodic patterns and calculates a pattern for preventing the moire phenomenon. will be.

In general, windows are installed in an opening of a building to block and open the outside. For indoor ventilation, these windows have a dual structure instead of the insect screen or together with the insect screen so as to prevent the inflow of yellow dust, fine dust, ultrafine dust, etc. (hereinafter, collectively referred to as fine dust) from the outside when the window is opened. Install a filter for blocking fine dust.

In general, a filter for blocking fine dust is composed of a mesh layer and a fiber layer having a mesh structure including a plurality of pores, and these filters pass through the fiber layer through the pores of the mesh layer, and fine dust existing in the outside air. As is collected in the fiber layer, there is an effect of blocking fine dust entering the room.

Meanwhile, the mesh structure of the mesh layer is formed to have a periodic pattern, and the fiber layer shows a periodic pattern with fibers having a specific period. The periodic patterns of the mesh layer and the fiber layer cause constructive interference by sunlight, and a unique pattern is generated (moire phenomenon) by the constructive interference, causing visibility problems. The moire phenomenon is a major cause of a defect in appearance of a window to which a filter is applied, and a technology for solving it is required.

The present invention is a method and apparatus for analyzing a moire phenomenon of a window filter for predicting a moire phenomenon caused by overlapping the periodic patterns in a window filter including a mesh layer and a fiber layer having different periodic patterns and calculating a pattern for preventing this It is a task to be solved to provide.

In order to solve the above problem, according to an aspect of the present invention, it is a method of analyzing a filter for windows and doors including a mesh layer having different periodic patterns and a fibrous layer provided on the mesh layer, and generating a moire phenomenon. The mesh layer and the fiber layer having a periodic pattern are converted into first and second matrices, respectively, and a first summation matrix having a pattern in which a moire phenomenon occurs is calculated based on the result of summing the converted first and second matrices. A first calculation step; A second calculation step of converting the pattern layer having an arbitrary pattern into a third matrix, and calculating a second summation matrix based on the result of the summation with the first summation matrix; And a determining step of determining whether or not a moire phenomenon occurs by comparing the first and second summation matrices. A method for analyzing a moire phenomenon of a window filter is provided.

As described above, the method and apparatus for analyzing a moire phenomenon of a window filter according to at least one embodiment of the present invention are provided in a window filter including a mesh layer having different periodic patterns and a fibrous layer provided on the mesh layer. By predicting the moire phenomenon that occurs and providing a pattern for preventing the moire phenomenon, it can be used to manufacture a filter for windows and doors in which the moire phenomenon is ultimately prevented.

1 is a block diagram of a method for analyzing a moire phenomenon of a window filter according to the present application.
2 is an exemplary diagram of a periodic pattern.
3 is a diagram illustrating a transformation of the periodic pattern shown in FIG. 2 into a matrix.
4 and 5 are conceptual diagrams for explaining a first calculation step.
6 and 7 are diagrams for explaining a second calculation step.
8 is a conceptual diagram illustrating an exemplary filter for windows and doors according to the present application.
9 and 10 are diagrams illustrating exemplary amorphous patterns for preventing moire.

The present application relates to a method for analyzing a moire phenomenon of a filter for windows and doors. First, the moire phenomenon refers to a phenomenon in which two or more periodic patterns are overlapped and interfere with each other to generate a wave pattern. The analysis method predicts a moire phenomenon of a filter for windows and doors, and provides a pattern for preventing the moire phenomenon.

Specifically, the analysis method according to the present application includes a mesh layer having different periodic patterns and a fibrous layer provided on the mesh layer, and is a method of analyzing a window filter in which a moire phenomenon occurs, wherein the moire phenomenon is the mesh layer and The different periodic patterns of the fibrous layer are caused by interference.

Hereinafter, a method for analyzing a moire phenomenon of a window filter according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

In addition, regardless of the reference numerals, the same or corresponding components are given the same or similar reference numbers, and redundant descriptions thereof will be omitted, and the size and shape of each component member shown for convenience of explanation are exaggerated or reduced. Can be.

1 is a block diagram of a method for analyzing a moire phenomenon of a window filter according to the present application. 2 is an exemplary diagram of a periodic pattern. 3 is a diagram illustrating a transformation of the periodic pattern shown in FIG. 2 into a matrix. 4 and 5 are conceptual diagrams for explaining a first calculation step. 6 and 7 are diagrams for explaining a second calculation step.

The analysis method includes a first calculation step (S100), a second calculation step (S200), and a determination step (S300).

In the first calculation step (S100), the mesh layer and the fiber layer having different periodic patterns are converted into first and second matrices 100 and 200, respectively, and the converted first and second matrices 100 and 200 Based on the summation result, a first summation matrix 300 in which a moire phenomenon occurs is calculated. The first summing matrix 300 may be a moire pattern or a moire pattern. Referring to FIG. 2, the periodic pattern means that the pattern area A and the non-pattern area B are regularly and repeatedly arranged or aligned.

The transformation is to image the mesh layer and the fiber layer of the window filter into a matrix having the same size (see Figs. 2 and 3), and this transformation can be performed using a Matlab program. The matrix may be expressed in the form of an NxM matrix. For example, the periodic patterns of FIGS. 2A to 2D may be transformed into matrices of FIGS. 3A to 3D to be imaged.

In addition, the summation simulates a process in which the periodic patterns of the mesh layer and the fiber layer of the window filter overlap each other to cause interference. The first summing matrix 300 is a simulation of a Moire pattern generated by two periodic patterns interfering (reinforcing interference) with each other, and such interference can be simulated by summing the first and second matrices 100 and 200. Yes (see Fig. 5).

6 and 7, in the second calculation step (S200), a pattern layer having an arbitrary pattern (400 in FIG. 6) is transformed into a third matrix (400 in FIG. 7), and summed with a first summation matrix. Based on the result, a second summation matrix (500 in Fig. 7) is calculated. The third matrix 400 is transformed into a matrix having the same size as the first summing matrix 300, and the second summing matrix 500 is also calculated with the same size as the first summing matrix 300. The second summing matrix 500 simulates a pattern generated when three periodic patterns interfere with each other. In other words, the second summing matrix 500 simulates a pattern generated by interference between the first summing matrix 300 and the random patterns of the pattern layer 400.

In the determining step (S300), it is determined whether or not a moire phenomenon occurs by comparing the first and second summing matrices 300 and 500.

Specifically, in the determination step S300, when the first summing matrix 300 and the second summing matrix 500 are different, it may be determined that the moire phenomenon is prevented. In other words, in the determination step (S300), when the first summing matrix 300 and the second summing matrix 500 are different, the random pattern of the pattern layer 400 causes destructive interference with the Moire pattern, resulting in a moire phenomenon. It can be judged as a pattern that prevents. Accordingly, when the pattern layer 400 having the arbitrary pattern is additionally introduced to the window filter including the mesh layer and the fiber layer, a filter for windows and doors in which the moire phenomenon is prevented can be provided.

The determining step S300 may further determine whether the second calculation step S200 is repeatedly performed by comparing the first and second summing matrices 300 and 500. Specifically, in the determination step S300, when the first and second summing matrices 300 and 500 are the same, it may be determined to repeatedly perform the second calculation step S200. For example, the determination step S300 may further determine whether to perform repetition, and ultimately provide a second summing matrix 500 different from the first summing matrix 300.

In one example, when iteratively performed, the second calculation step (S200) converts the new pattern layer 400 having a different random pattern from the previously performed second calculation step (S200) into the third matrix 400. I can. The iterative execution process corresponds to a process of finding a random pattern capable of preventing the moire phenomenon by causing destructive interference with the moire pattern. Accordingly, the repetition may be repeated until the first summing matrix 300 and the second summing matrix 500 are different from each other.

In one example, the transformation may be given to different values for the pattern area and the non-pattern area of the periodic pattern. The transformation may be applied to a matrix by assigning a pattern region and a non-pattern region as values of '1' or '0', respectively, using a binary method. For example, in the transformation, a pattern area may be assigned as '1' and a non-pattern area may be assigned as '0'.

When the periodic pattern is described in detail, the mesh layer may have a mesh structure in which a plurality of voids are formed, and the mesh structure may have a periodic pattern shape. For example, the periodic pattern of the mesh layer means that a plurality of pores are regularly and repeatedly arranged or aligned. Here, in the transformation, the skeleton of the mesh structure can be given as '1' and the void can be given as '0'. Similarly, the conversion degree of the fiber layer can be given as '1' to the area in which the fibers are distributed and '0' to the area in which the fibers are not arranged.

In one embodiment, the summation may give different values to the area where the pattern area overlaps and the area where the pattern area overlaps and the non-overlapping area. Specifically, the area in which the pattern areas overlap refers to an area in which the pattern area to which '1' of the mesh layer is applied and the pattern area to which '1' of the fiber layer is assigned are matrix summed to become '2'. On the other hand, in the non-overlapping area, the non-pattern area with '0' of the mesh layer and the non-pattern area with '0' of the fiber layer are matrix summed, and the area that becomes '0' and '1' of the mesh layer are given It refers to a region in which the patterned area and the non-patterned area to which '0' is assigned to the fiber layer are summed in a matrix to become '1'. Naturally, the area in which the pattern area to which '0' is assigned to the mesh layer and the pattern area to which '1' to the fiber layer is assigned is matrix summed to become '1' also corresponds to the non-overlapping area.

For example, in the summation, a value of '1' may be added to the area where the pattern area overlaps, that is, the area that becomes '2' as a result of matrix summation. In addition, a value of '0' may be given again to a non-overlapping area, that is, an area that becomes '1' or '0' as a result of matrix summation.

In the first summing matrix 300, an overlapping area may be a pattern area, and a non-overlapping area may be a non-pattern area. In addition, since the second summing matrix 500 is calculated as a result of summing the first summing matrix 300 and the third matrix 400, the second summing matrix 500 is a pattern of the first summing matrix 300 The overlapping area between the area and the pattern area of the third matrix 400 may be a pattern area (see FIG. 5 ).

In one embodiment, the random pattern may be an amorphous pattern. The amorphous pattern refers to a pattern having a non-uniform appearance, and in a different meaning, refers to a pattern in which a periodic pattern does not appear. In the case of an amorphous pattern that calculates the second summing matrix 500 different from the first summing matrix 300, when applied to the pattern layer 400 of an actual window filter, it is shown by constructive interference of the periodic patterns of the mesh layer and the fiber layer. There is an effect of preventing the moire phenomenon by causing destructive interference with the moire pattern.

The present application also relates to an apparatus for analyzing a moire phenomenon of a filter for windows and doors. Since the device uses the above-described analysis method, detailed descriptions of duplicated content will be omitted below. The device may be, for example, a device using a Matlab program.

Specifically, the device includes a first calculation unit, a second calculation unit, and a determination unit.

The first calculation unit converts different periodic patterns of the mesh layer and the fiber layer into first and second matrices 100 and 200, respectively, and a result of summing the converted first and second matrices 100 and 200 Based on this, a first summation matrix 300 in which a moire phenomenon occurs is calculated.

The second calculation unit converts the pattern layer 400 having an arbitrary pattern into a third matrix 400 and calculates a second summing matrix 500 based on a result of summing the pattern layer 400 with the first to third matrices 400. Calculate.

The determination unit compares the first and second summing matrices 300 and 500 to determine whether a moire phenomenon occurs.

The present application also relates to a filter for windows and doors. The filter may be a filter for windows and doors in which a moire phenomenon is prevented.

8 is a conceptual diagram illustrating an exemplary filter for windows and doors according to the present application. 9 to 13 are diagrams showing exemplary amorphous patterns for preventing moire phenomenon.

The window filter includes a mesh layer 10, a pattern layer 20, and a fiber layer 30.

Specifically, the mesh layer 10 has a first surface 11 and a second surface 12 opposite to the first surface 11. The first surface 11 of the mesh layer 10 refers to a surface facing outdoors when a window is applied, and, for example, refers to a surface to which sunlight is irradiated when a window is applied. The mesh layer 10 has a mesh structure in which a plurality of voids are formed, and the mesh structure may have a periodic pattern.

The pattern layer 20 is provided on the first surface 11 of the mesh layer 10, and an arbitrary pattern is formed according to the above-described analysis method or analysis device. In addition, the fibrous layer 30 is provided on the second surface 12 of the mesh layer 10. The arbitrary pattern formed on the pattern layer 20 may be an arbitrary pattern that calculates a second summing matrix 500 different from the first summing matrix 300 in the above-described analysis method or apparatus. Alternatively, it may mean a pattern that causes destructive interference with the Moire pattern of the first summing matrix 300.

The fibrous layer 30 may have a first surface to which the mesh layer 10 is bonded and a second surface to which the mesh layer is not bonded. Specifically, the fibrous layer 30 includes fibers having a periodic pattern (a specific period), and the periodic pattern of such fibers may cause reinforcing interference with a periodic pattern due to the mesh structure of the mesh layer, thereby causing a moire phenomenon. . However, the filter for windows and doors according to the present application may cancel the constructive interference as a random pattern according to the above-described analysis method or apparatus is introduced, thereby preventing a moire phenomenon.

In one example, the arbitrary pattern may be an amorphous pattern. Such an amorphous pattern can prevent moire and at the same time provide an aesthetic value by being manufactured in a luxurious design (see FIGS. 9 and 10).

Preferred embodiments of the present invention described above are disclosed for the purpose of illustration, and those skilled in the art having ordinary knowledge of the present invention will be able to make various modifications, changes, and additions within the spirit and scope of the present invention. And additions will be seen as falling within the scope of the following claims.

10: mesh layer
11: first page
12: second side
20: pattern layer
30: fiber layer

Claims (13)

It is a method of analyzing a filter for windows and doors that includes a mesh layer having different periodic patterns and a fibrous layer provided on the mesh layer, and in which a moire phenomenon occurs,
A first summation matrix having a pattern in which a moire phenomenon occurs based on the result of converting the mesh layer and the fiber layer having different periodic patterns into first and second matrices, respectively, and summing the transformed first and second matrices A first calculation step of calculating a;
A second calculation step of converting the pattern layer having an arbitrary pattern into a third matrix, and calculating a second summation matrix based on the result of the summation with the first summation matrix; And
And a determining step of determining whether or not a moire phenomenon occurs by comparing the first and second summation matrices. The method of claim 1, wherein when the first and second summing matrices are different from each other, it is determined that the moire phenomenon is prevented. The method of claim 1, wherein the determining step further determines whether or not the second calculation step is repeatedly performed by comparing the first and second summing matrices. The method of claim 3, wherein the determining step is to repeat the second calculation step when the first and second summating matrices are the same. The method of claim 4, wherein when repeatedly performed, the second calculation step converts a new pattern layer having a different random pattern from the previously performed second calculation step into a third matrix. The method of claim 1, wherein the transformation is applied to a pattern region and a non-pattern region of a periodic pattern as different values, respectively. The method of claim 1, wherein the summation gives different values to the regions where the pattern regions overlap and the non-overlapping regions, respectively. 8. The method of claim 7, wherein in the first summation matrix, the overlapping area is a pattern area, and the non-overlapping area is a non-pattern area. The method of claim 1, wherein the determining step further determines whether the second calculation step is repeatedly performed based on whether the moire phenomenon has occurred. The method of claim 1, wherein the random pattern is an amorphous pattern. It is a device for analyzing a filter for windows and doors that includes a mesh layer having different periodic patterns and a fibrous layer provided on the mesh layer, and generates a moire phenomenon,
Converting different periodic patterns of the mesh layer and fiber layer into first and second matrices, respectively, and calculating a first summation matrix in which a moire phenomenon occurs based on a result of summing the transformed first and second matrices. A first calculation unit;
A second calculator configured to convert a pattern layer having an arbitrary pattern into a third matrix and calculate a second summation matrix based on a result of summation with the first to third matrices; And
And a determination unit that compares the first and second summing matrices to determine whether or not a moire phenomenon occurs. A mesh layer having a first surface and a second surface opposite to the first surface;
A pattern layer provided on the first surface of the mesh layer and having an arbitrary pattern formed according to the analysis method of claim 1 or the analysis device of claim 8; And
A filter for windows and doors comprising a fibrous layer provided on the second side of the mesh layer. The filter for windows and doors according to claim 12, wherein the pattern layer is formed by transferring an arbitrary pattern according to the analysis method according to claim 1 or an analysis device to the first surface of the mesh layer.

Images