WO2015152576A1 - Multi- position array structure and display device therefor - Google Patents

Abstract

Disclosed is a multi-position array structure (210) in which placement positions of various arrangements are arranged to overlap. Specifically, disclosed are a multi-position array structure and a display device therefor which include: a multi-position linear array structure; a multi-position planar array structure; a multi-position circular array structure; and a multi-position disc array structure, and which implement an image with placement of arrangements.

Description

Multi-position array structure and its display device

The present invention relates to an arrangement structure having a receiving portion for partitioning each arrangement position such that the arrangement positions of the arrangements are arranged so as to be continuously overlapped, and in particular, to continuously arrange the arrangement positions for effective image realization through placement of the arrangements. The present invention relates to a multi-position array structure that provides a variety of arrangement methods and a display device thereof.

Conventional arrangements implement an image by placing the arrangement in a plurality of independent placement positions on which the arrangement to be arranged (the arrangement can be placed in a certain arrangement) is embodied, or an iteration of the arrangement. It has been used for the purpose of making this possible. An example of conceptually describing an implementation of an image in a conventional arrangement structure is a screen display device.

In general, a screen display device configures a screen by arranging pixels (pixels). The display performance of one screen display apparatus may be classified into resolution, and the resolution determining factor may be referred to as the size and number of pixels.

Since the size of a pixel constituting one screen display device and the number of pixels are closely related, the maximum resolution that can be realized by arranging pixels of a constant size in a constant screen width is fixed.

According to the conventional arrangement structure, the maximum resolution of the screen display device that can be implemented within a certain screen display area is determined by the size of the pixel. If the size of the pixel and the screen display area are constant, the number of pixels that can be arranged on the screen display device is specified.

In electronic display devices (LEDs, LCD monitors, etc.), there are many products in which a screen display device is configured by arranging very small pixels that are difficult to be identified by the human eye. However, in everyday life, there are products that are difficult to change or reduce the size of pixels due to economic efficiency or technical problems.

As an example, a playground equipment in which children place arrangements (as objects corresponding to pixels) by hand on array boards with certain rules to implement an image, the arrangements being of constant size to suit children's playability. Will have to.

As another example, in the case of realizing a specific image by using a light source arrangement (as an object corresponding to a pixel) in an advertisement such as a signboard, a light source having a reaching distance suitable for the purpose of the signboard is used as the arrangement. There will be limitations to making the light source arrangement small as it must be used.

According to the present invention, when it is difficult to reduce the size of the batch or increase the overall size of the arrangement, technically or economically, or without reducing the size of the arrangement or increasing the overall size of the arrangement, The present invention relates to an array structure for increasing the resolution or the quality of an image and a display device thereof.

The 'multi-position arrangement structure' included in the present invention includes a multi-position arrangement in which the arrangement positions of the arrangements are continuously overlapped, so that the number and arrangement combinations of placement positions that can selectively arrange the arrangements are more various. Detailed images can be implemented.

The multi-position array structure may also include the following four arrangement structures to correspond to the implementation of various images.

1) Multi-position linear array structure-It is a structure derived from the concept of multi-position linear array in which the arrangement positions of the batches are continuously overlapped on one straight line or curve. You can place the layout to create an image that contains various points and lines.

2) Multi-position planar array structure-It is a structure in which the multi-position linear array is repeated in a plurality or more and expanded in the form of plane. The arrangement may be arranged to implement two-dimensional images of various shapes.

3) Multi-Position Circular Arrangement-This structure is derived from the concept of multi-position circular array, which is composed by dividing the placement positions of the batches on one circumference at equal intervals. The layout can be placed to produce an image containing a circle or arc of various points and lines.

4) Multi-Position Disk Array Structure-The multi-position circular array is a structure in which the multi-position circular array is repeated in a plurality of concentric circles and extended to a disk surface or a donut-shaped (empty center) surface. The arrangement can be placed to produce images of various shapes, including circles and arcs.

Details of the multi-position array structure and its display device of the present invention will be described with reference to the accompanying drawings in the detailed description of the invention.

The 'multi-position array structure' included in the present invention is a structure for controlling the degree of overlap (overlapping) according to the intended use, and also because it is infinitely expandable structure, it can be utilized in various industrial fields.

1) In order to economically produce a product that meets the needs of a segmented consumer, a unified production method that can accommodate a large number of demands is required. Take a street sign that is easily accessible, for example, currently manufactured signboards can be arranged to arrange light sources (in this case, batches) using specially designed array plates to create the name or image of individual companies, or It is manufactured by combining light sources with separate acrylic sculptures or screens that are manufactured according to their names or images.

If the multi-position array structure of the present invention and its display device are combined in this field, it is possible to implement a signboard production method of a unified standard corresponding to the names and images of various companies.

2) The conventional arrangement method has been used in various fields for the production of play equipment for infants and children. If the multi-position array structure and the display device of the present invention are applied to the educational field of manually placing the arrangement, it will be a textbook for acquiring a creative arrangement as a play equipment for infants.

3) Due to its simplicity, the existing arrangement has been incorporated into production at the infant and child level. However, the multi-position array structure can be applied to a hobby item that can be used by a wide range of objects including adults because of its complex arrangement.

As a conventional hobby item such as a cross-stitch embodies an image using a thread of various colors, the hobby item to which a multi-position array structure is applied may be a hobby item to embody an image using a batch of various colors.

1 is a conceptual diagram of a multi-position array structure, illustrating a multi-position array.

2 is a conceptual diagram of a multi-position array structure, which illustrates the provision of a groove as a receiving portion.

3 is a conceptual diagram of a multi-position array structure, which illustrates an arrangement column as a receiving portion.

4 is a conceptual diagram of a multi-position array structure, illustrating the display portion and the engaging portion of the arrangement.

5 is a conceptual diagram of a multi-position array structure, illustrating a cross section of a batch coupling portion.

6 is a conceptual diagram of a multi-position array structure, illustrating the correlation between the shape of the arrangement position and the arrangement groove.

7 is a conceptual diagram of a multi-position array structure, illustrating the correlation between the shape of the arrangement position and the arrangement column.

8 is a conceptual diagram of a multi-position array structure, illustrating the correlation between arrangement positions having different shapes.

9 is a conceptual diagram of a multi-position array structure, illustrating the structures of various array columns.

10 is a conceptual diagram of a multi-position array structure, illustrating the position and shape of the array column.

11 is a conceptual diagram of a multi-position array structure, illustrating an array column according to the shape of the arrangement position.

10 is a schematic view of a multi-position array structure, which is a conceptual diagram of a multi-position array structure having an arrangement groove.

11 is a conceptual diagram of a multi-position array structure having array columns.

12 is a representation of an embodiment of a multi-position array structure.

Figure 13 is an embodiment of a multi-position array structure provided with an array column.

14 is a configuration diagram of a multi-position array structure.

15 shows a first embodiment of a multi-position linear array.

16 shows a second embodiment of a multi-position linear array.

Figure 17 shows Embodiment 3 of a multi-position linear array.

18 shows Example 4 of a multi-position linear array.

19 is a perspective view and a front view showing an arrangement groove of a multi-position linear array structure;

20 is a perspective view and a front view showing an array column of a multi-position linear array structure;

21 shows Embodiment 1 of a multi-position planar array

22 shows a second embodiment of a multi-position planar array.

FIG. 23 is a partially enlarged view of the arrangement pillar of FIG. 21.

24 is an embodiment provided with a partially enlarged arrangement column of FIG.

25 is a perspective view and a front view of a multi-position planar array in a partial embodiment of FIG. 21.

FIG. 26 is a perspective view and a front view of the multi-position planar array according to the partial embodiment of FIG.

27 is a conceptual diagram of a multi-position circular array component

28 is a conceptual diagram of a multi-position circular array

29 is a partial enlarged view of the arrangement pillar conceptual diagram of FIG.

30 is a perspective view and front view of the multi-position circular array structure in the embodiment of FIG.

31 is a conceptual diagram of a multi-positional disc array

32 is a perspective view and a front view of a multi-position disc array structure embodiment

33 illustrates an embodiment of a multi-position array structure display device.

34 is a cross-sectional view of FIG. 33

Hereinafter, various embodiments of the present invention will be described in detail with reference to the accompanying drawings. Since the embodiments described below may be variously modified, the scope of the present invention is not limited to the described embodiments. In addition, the drawings accompanying the embodiments may be exaggerated for showing the components for the purpose of explanation.

Since the present invention is based on a plurality of logical concepts, prior to the description of the specific embodiment, the arrangement with the multi-position array 110, the arrangement position 301, and the accommodating part 310, which are commonly included in the specific embodiments, are included. The main elements of the multi-position array structure, such as water 331, will be described first in FIGS. 1 to 11.

12 and 13 illustrate exemplary embodiments of a multi-position array structure.

After explaining the configuration of the multi-position array structure in FIG. 14, specific embodiments included in the present invention will be described in detail from FIG. 15.

1 is a conceptual diagram illustrating a multi-position array 110 which is distinguished from a conventional arrangement.

The multi-position array 110 is an arrangement method included in the multi-position array structure 210 according to the present invention. As shown in the conceptual diagram, the multi-position array 110 is not only composed of one overlapping array, but also the multi-position array 110 in a plurality of arrangements. It can also be configured. In FIG. 1, only one arrangement is illustrated and described in order to avoid complexity of description.

The conceptual location (or placement location 301) where the placement 331 can be placed on the surface 351 is indicated by thirteen circles a01-a13, with each circle representing a placement 331b, 331g. 331m), the bottom surface shape (or arrangement position) 301 is shown.

The multi-position array 110 included in the multi-position array structure of the present invention; It may be said that a plurality of arrangement positions 301 are arranged in such a way that a part of them are arranged in succession. In addition, the multi-position array 110 is not limited to the overlapping arrangement illustrated in FIG. 1, and the overlapping arrangement may be achieved by the number of various arrangement positions by adjusting the overlapping degree.

Referring to FIG. 1, a1, a2, and a3 are conceptually arranged in the arrangement position 301, so that if the arrangement 331 is arranged in the arrangement position a2, the arrangement may not be arranged together in the a1 and a3 arrangement. . However, if the placement position 301 is optionally determined, the placement 331 may be arranged either in a1 or in a2 and in a3. The multi-position array 110 is characterized by having a plurality of arrangement positions 301 selectable.

Referring to FIG. 1, two arrangements 331g and 331m are arranged at a2 and a4 at five arrangement positions 301 a1 to a5, respectively. The two arrangements 331g and 331m can be arranged not only adjacent to a2 and a4 as shown in the drawings among the arrangement positions a1 to a5, but also adjacent to a1 and a3, and a3 And a5 may also be disposed adjacently. In addition, two non-adjacent arrangements 331g and 331m may be arranged in a1 and a4, may be arranged in a2 and a5, and may also be arranged in a1 and a5.

The number of combinations for arranging the two arrangements 331g and 331m will allow more combinations of the number as the width of the placement position to be arranged is wider than a1 to a5, and the arrangement 331 to be arranged. It is understood that more batch combinations are possible with increasing numbers of.

Referring to FIG. 1, the multi-position array 110 may not only include a plurality of arrangement positions 301 which can be selectively arranged, but also various combinations may be arranged when a plurality of arrangements 331 are arranged. I can understand that.

If the multi-position array 110 described in FIG. 1 was a logical concept, FIGS. 2 and 3 show a multi-position with a receiving portion 310 in which the multi-position array 110 can actually receive the arrangement 331. It is a conceptual diagram for embodying the arrangement structure 210.

Referring to FIG. 2, each of the thirteen arrangement positions 301 illustrated in FIG. 1 is partitioned to accommodate the arrangement 331, and has a structure in which a groove is formed in the surface 351 to form an arrangement groove 311. Is shown conceptually. The arrangement groove 311 may constitute a receiving portion 310 that determines the placement position 301 of the placement 331.

Referring to FIG. 2, it may be understood that the multi-position array 110 includes a receiving unit 310 to form a multi-position array structure.

In FIG. 2, three batches 331b, 331g, 331m, which have been arranged by way of example in FIG. 1, are placed by way of example in the same position.

Referring to FIG. 3, the array columns 321 around the placement position 301 on the surface 351 so that each of the thirteen placement positions 301 shown in FIG. 1 can be partitioned to accommodate the arrangement 331. Conceptually illustrated structure with a. The arrangement pillar 321 may form a receiving portion 310 that determines the placement position 301 of the arrangement 331.

Referring to FIG. 3, it can be understood that the multi-position array 110 may include a receiver 310 capable of arranging the arrangement to form a multi-position array structure.

In FIG. 3, three batches 331b, 331g, 331m, which were arranged by way of example in FIG. 1, are placed by way of example in the same position.

The four array columns a21, a22, a23, and a24 may form a pair to partition the arrangement position 301 of one arrangement 331. Also, among the four array columns a21, a22, a23, and a24, the two array columns a21 and a22 may be commonly used to partition the arrangement position 301 of the adjacent arrangement 331b.

4 and 5 are conceptual views illustrating examples of a multi-position array structure 210 and a layout 331 applicable to the display device of the present invention. Examples of the arrangement 331 shown in FIGS. 4 and 5 do not include a view applied to the multi-position array structure 210 in relation to the ground of FIGS. 4 and 5, but at least one in the following figures. As an example, the multi-position array structure 210 is included.

4 shows a perspective view a30, a side view a31 and a front view a32 of three arrangements 331b, 331m, and 331h. It is an example showing that arrangements having structures of different display portions a41 and coupling portions a42 may be included in the multi-position array structure 210.

The three arrangements 331b, 331m, and 331h have structures of different display portions a41 and coupling portions a42. The first arrangement 331b and the second arrangement 331m of FIG. 3 are examples of a structure in which the display portion and the coupling portion are divided, and the third arrangement 331h is an example in which the coupling portion and the display portion have an integral structure.

In addition, referring to the perspective view (a30) and the front view (a32), unlike the other two arrangements (331b, 331m), the second arrangement (331b), the cross section (a46) of the display portion and the cross section (a45) of the coupling portion is asymmetrical Illustrate the structure.

5 shows an example of five batches 331b, 331d, 331g, 331h, 331m, where a batch 331 having cross-sections (or bottoms) of various joining portions is arranged in a multi-position array structure 210. It can be included.

Referring to the perspective view a50, front view a51, side view a52, and cross-sectional view a53, or the bottom surface of the layout of FIG. 5, the layout 331b corresponds to a circular placement position 301b, The arrangement 331d corresponds to the triangular arrangement position 301d, the arrangement 331g corresponds to the octagonal arrangement position 301g, and the arrangement 331h corresponds to the octagonal arrangement position 301g, The arrangement 331m corresponds to the circular arrangement position 301b, respectively.

As shown in FIG. 5, the multi-position array structure 210 of the present invention may include placement positions corresponding to placements having cross-sections (or in the form of bottoms) of various coupling portions. It is possible to achieve a multi-position array structure 210 including various arrangement positions, including polygons and circles, such as triangles, hexagons, octagons.

6 and 7 include a receiving portion 310 according to the shape of the placement position 301 corresponding to the cross section (or bottom surface) of the engaging portion of the arrangement 331, thereby forming a multi-position arrangement structure 210. Each is a perspective view and a front view for an example.

Referring to the perspective view and the front view of FIG. 6, four arrangement positions 301b, 301d, 301f, and 301g corresponding to the cross section (or bottom surface) of the respective engagement portions of the four arrangements 331b, 331d, 331f, and 331g. An example of a multi-position array structure 210 including an array groove 311 according to the present invention is shown. It will be appreciated that the multi-position array structure 210 may include a receiving portion 310 corresponding to the shape of various arrangement positions 301.

Referring to the perspective view and the front view of FIG. 7, four arrangement positions 301b, 301d, 301f, and 301g corresponding to the cross section (or bottom surface) of the respective engagement portions of the four arrangements 331b, 331d, 331f, and 331g. An example of a multi-position array structure 210 including an array column 321 is shown. It will be appreciated that the multi-position array structure 210 may include a receiving portion 310 corresponding to the shape of various arrangement positions 301.

FIG. 8 is a cross-sectional view (or bottom surface) of various coupling portions provided with the receiving portion 310 according to a circular arrangement position 301b, even if the shape of the coupling portion of the arrangement 331 is different. A perspective view a70, a side view a71, and a front view a72 of a conceptual view illustrating that a multi-position array structure 210 may be configured to include a batch having the form of.

The embodiment of the multi-position array structure 210 of FIG. 8 includes an arrangement groove 311 configured to receive the arrangement 331b corresponding to the circular arrangement position 301b. The multi-position array structure 210 of FIG. 8 can accommodate (or arrange) the arrangement 331b having a circular arrangement position 301b, as well as a hexagonal arrangement position 301f and an octagonal arrangement position ( 301h) and some modified circular placement positions 331k, which may accommodate (or arrange) various shaped arrangements 331f, 331h, 331k.

A73 in FIG. 8 shows the cross section (or bottom surface) and the shape of the arrangement position of the engaging portion of the arrangement. It is understood that the hexagonal arrangement position 301f is inscribed in the circular arrangement position 301b, and the octagonal arrangement position 301h is also inscribed in the circular arrangement position 301b.

FIG. 9 illustrates a structure of an array column that divides individual arrangement positions 301 at a plurality of arrangement positions 301 that overlap and form a multi-position arrangement.

Referring to b10 of FIG. 9, one arrangement position 301 and 301b may be partitioned by four array columns 321. Four array columns may have one arrangement position 301b and four contacts b11, b12, b13, and b14. The four contacts b11, b12, b13, and b14 may have four virtual line segments that are adjacent to the adjacent contacts. For example, two contact points b11 and b12 may be connected to form a virtual line segment b15. The length of each of these imaginary line segments may be shorter than the diameter of the placement position 301b.

Referring to b20 of FIG. 9, one arrangement position 301 and 301b may be partitioned by three array columns 321. Three array columns may have an arrangement position 301b and three contacts b21, b22, and b23. The three contacts b21, b22, and b23 may have three virtual line segments connected to adjacent contacts. For example, two contacts b21 and b23 may be connected to form a virtual line segment b24. Each of these virtual line segments may be shorter than the diameter of the placement position 301b.

Referring to b26 of FIG. 9, one arrangement position 301, 301f may be partitioned by three or more arrangement pillars 321.

Referring to b27 of FIG. 9, one arrangement position 301 and 301g may be partitioned with the array pillar 321 in tangent.

9 is a front view and a perspective view showing an embodiment of the alignment column described in b10, b20, b26, and b27.

10 illustrates an embodiment of a multi-position array structure, which illustrates the position and shape of the array column.

Referring to b30 and b40 of FIG. 10, any two arrangement positions 301 arranged in succession may have two virtual line segments. One is an overlapping center line 113 penetrating two contacts b33, which have two adjacent arrangement positions 301 overlapping, and the other is an arrangement circumference line 112 circumscribed (b31) at two adjacent arrangement positions. . The array circumference 112 may be two above and below two adjacent arrangement positions.

Referring to b40 of FIG. 10, an array pillar 321 may be provided to partition two consecutively arranged arrangement positions 301, and the circular array pillars 321 and b41 may have an array pillar center point 322. ) As the contact point between the two arrayed tangential line 112 and the overlapping center line 113 may have two arrangement positions and contacts.

In addition, it may be provided with a circular array column (321, b43) to partition each of the two consecutively arranged arrangement position 301, the circular array column (321, b43) is the center point of the overlapping center line 113 It can be located on and have contacts with two placement positions.

Referring to b30 and b40 of FIG. 10, any two arrangement positions 301 arranged in succession may have one virtual region b35. The virtual area b35 is an array circumference 112 which is circumscribed b31 at two adjacent arrangement positions and a virtual area b35 which is divided by the two arrangement positions 301. The array column 321 included in the multi-position array structure 210 preferably has contacts or tangents corresponding to the two arrangement positions 301 in the virtual area b35, respectively.

Referring to b40 of FIG. 10, an array column b44 having an arbitrary shape may have contact points with the two arrangement positions 301 in the virtual area b35, respectively.

Referring to b40 of FIG. 10, a circular array column b42 may be provided to partition each of two consecutively arranged arrangement positions 301, and the circular array column b42 may have a center point as the overlapping center line. It may be positioned on 113 and may have contact with two arrangement positions, and the array pillar b42 may be located in the virtual area b35.

11 is a conceptual diagram of a multi-position array structure, illustrating an array column according to the shape of the arrangement position.

Referring to b50 and b60 of FIG. 11, a circular array column 321 may be provided to partition two consecutively arranged arrangement positions 301, and the circular array column 321 may have an array column center point. 322 may be a contact point between the array circumference line 112 and the overlapping center line 113 and may have two adjacent arrangement positions and contacts.

Referring to b70 of FIG. 11, when there is no region capable of providing an array pillar between the array circumference line 112 and the arrangement position, an arbitrary line segment b72 and an array circumference line parallel to the array circumference line 112 are provided. The array column center point 322 may be provided at the contact point 113, and the array column may have the arrangement position and the contact point.

Reducing to the description of FIGS. 1 to 11,

Multi-position array structure,

As an arrangement structure corresponding to the shape of various batches,

The arrangement may be arranged by successively overlapping the placement position of the placement on the surface,

Multiple arrangement positions arranged in an overlap form a multi-position arrangement,

Each arrangement position constituting the multi-position arrangement may be partitioned by the receiving portion,

Receiving portion for partitioning the arrangement position comprises a groove of various shapes or array columns of various shapes and numbers,

An image may be embodied by selectively placing a batch in a plurality of partitioned receiving portions.

FIG. 12 shows an embodiment of a multi-position array structure 210 with an arrangement groove, as a representative view of the multi-position array structure.

An array groove 311 is provided on the surface to form a multi-position array structure 210 including a multi-position planar array structure 230 and a multi-position disc array structure 250. Optionally, the layouts 331m and 331b are formed. Arrange and optionally adjust the spacing between batches to produce any image.

FIG. 13 illustrates an embodiment of a multi-position array structure 210 as shown in FIG. 12 above.

The array column 321 is provided on the surface to form the multi-position array structure 230 including the multi-position surface array structure 230 and the multi-position disc array structure 250, and the arrangements 331m and 331b are selectively provided. Can be placed to implement any image.

14 is a relationship diagram of a main embodiment of a multi-position array structure.

The relationship diagram of the main embodiment of the multi-position array structure 210 shares an example and a concept with the above-described examples of FIGS. 1 to 13, while corresponding to each of the linear and planar, circular and disk-shaped images and combinations thereof. Description of.

Referring to Figure 14, the multi-position array structure 210,

A multi-position linear array structure 220 which is a first embodiment;

A multi-position planar array structure 230 which is a second embodiment;

A multi-position circular array structure 240 which is a third embodiment;

A fourth embodiment of the multi-position disc array structure 250; And

In the first to fourth embodiments, the multi-position array structure display device 270 further includes a power supply unit and an electrode.

The multi-position linear array structure 220 according to the first embodiment includes a multi-position linear array 120 that continuously arranges the arrangement positions 301 on a line.

The multi-position planar array structure 230 according to the second embodiment includes the multi-position linear array 120; A multi-position plane array 130 for repeating the multi-position linear array 120 in a vertical direction; And a multi-position linear array structure 220.

The multi-position circular array structure 240, which is the third embodiment, includes a multi-position circular array 140 which continuously arranges the arrangement position 301 on the circumference.

The multi-position disc array 250 according to the fourth embodiment includes the multi-position disc array 140; A multi-position disc array 150 for repeating the multi-position circle array 140 concentrically; And a multi-position circular array structure 240.

Multi-position array structure 210 of the present invention includes a multi-position array 110 (not shown),

The multi-position array 110 includes a multi-position plane array 130 and a multi-position disc array 150. The multi-position planar array 130 includes a multi-position linear array 120. The multi-position disc array 150 includes a multi-position disc array 140.

15 to 34, the main embodiments of the present invention will be described.

15 to 20, an embodiment of the multi-position linear array structure 220 included in the multi-position array structure 210 will be described.

FIG. 15 illustrates two embodiments of the multi-position linear array 120 included in the multi-position linear array structure 220, in which the two positions overlap at equal intervals in the horizontal direction 352. It can have regularity that is arranged. The two embodiments also illustrate a portion of multi-position linear array 120 that is infinitely expandable.

Referring to FIG. 15, the multi-position linear array 120 may be classified into a multi-position linear array 120a and a multi-position linear array 120b, and the two arrangements overlap the placement positions 301 on the surface. Each arrangement position center point 302 is arranged so as to coincide with the intersection of the equidistant lines 123 and the multi-position linear array center line 122.

The horizontal direction 352 is perpendicular to the equal intervals 123 to serve as an arrangement reference for the equal intervals. Since the plurality of equidistant lines 123 are arranged with the same horizontal array interval (or horizontal distance between centers of the arrangement positions, AL) in the horizontal direction 352, the plurality of arrangements including one multi-position linear array 120 The locations may be arranged at equal intervals.

In FIG. 15A, the arrangement position 301 is overlapped on the multi-position linear array centerline 122 parallel to the horizontal direction for convenience of description, but the multi-position linear array centerline 122 is parallel to the horizontal direction. You can't.

The multi-position linear array 120a may move each arrangement position 301 on each equidistant line 123 as long as it maintains the overlap, thereby converting the multi-position linear array 120b. It can be understood that 120a and 120b of FIG.

The multi-position curved array center line 122b is composed of inflection points having a radius of curvature of the placement position width WP or more, and is not parallel to the equidistant line 123. (Not shown)

Since the equal spacing line 123 and the multi-position linear array center line 122 can be extended indefinitely, the number of arrangementable positions can also be increased to infinite by extending the multi-position linear array.

In order to effectively implement the multi-position linear array 120, the following conditions must be satisfied.

1. The overlap array spacing (WA) and overlap width (WV) may be less than the positionable position width (WP) and may be greater than zero (number).

2. The overlapping spacing (WA) and the horizontal distance (AL) between the centers of the placement positions may be the same.

3. The sum of the overlapping array spacing WA and the overlapping width WV may be equal to the placement position width WP.

4. Since the overlap array spacing (WA) is equal to the horizontal distance (AL) between the centers of the arrangement positions, AL + WV = WP can be satisfied.

5. If the number of all batch positions constituting the multi-position linear array is WN (WN is a natural number of 2 or more), the multi-position linear array width (WL) can be expressed as the following formula.

(WN * WA) + WV = WL, or (WN * AL) + WV = WL,

Or {(WN-1) * AL} + WP = WL

16 and 17 show the multi-position linear array width WL and the arrangement position width WP, among the components used in the example of the multi-position linear array 120 of FIG. 15, but between centers of the placement positions. The embodiment illustrates a multi-position linear array 120 having a difference in the horizontal distance AL.

16 and 17, two multi-position linear arrays 120a and 120b to which the horizontal distance AL1 between the centers of the two arrangement positions and the horizontal distance AL between the centers of the arrangement positions are applied are illustrated. . The multi-position linear array (120, WN = 13) applying the horizontal distance (AL1) between the centers of the placement positions is larger than the multi-position linear array (120, WN = 5) applying the horizontal distance (AL) between the centers of the placement positions. Arrangement positions of may overlap. Various overlapping can be achieved by adjusting the horizontal distance between the centers of the arrangement positions, thereby adjusting the degree of overlap (overlap degree) of the arrangement positions to form a multi-position linear array consisting of the number of various arrangement positions.

16 and 17, when the multi-position linear array width WL and the dispositionable position width WP are constant, the overlapping width according to the number WN of dispositionable positions W The formula for calculating the value of WV or WV1) is derived as follows.

Since WA = WP-WV, the formula (WN * WA) + WV = WL can be converted to

{WN * (WP-WV)} + WV = WL

(WN * WP)-(WN * WV) + WV = WL

(WN * WP)-(WN-1) * WV = WL

{(WN * WP)-WL} / (WN-1) = WV

Using the above formula, when the batch position width (WP) and the multi-position linear array width (WL) are constant, the WV value can be obtained by substituting any two or more natural numbers into the WN. However, to satisfy the condition of overlap, the condition of (WN * WP)-WL> 0 (number) can be established.

The multi-position linear array 120 including the multi-position linear array and the multi-position linear array can be infinitely extended, and can be infinitely overlapped based on mathematical correlation between the components.

FIG. 18 shows the arrangement position width in the condition that the horizontal distance AL between the centers of the arrangement positions and the number WN of the arrangement positions are the same among the components used in the example of the multi-position linear array 120 of FIG. 15. A conceptual diagram illustrating a multi-positional curve array with a difference in (WP). (Drawings of multi-position linear arrays showing the same result are omitted.)

Referring to the equation {(WN-1) * AL} + WP = WL of the multi-position linear array width, the multi-position linear array width (WL2) is calculated when the WP value fluctuates to WP2 under the same conditions. You can get it.

If the value of WP in the formula {(WN-1) * AL} + WP = WL fluctuates to WP2, and the change is called WPp (WP2-WP = WPp),

Since {(WN-1) * AL} + WP + WPp = WL + WPp = WL2,

WL2-WPp = WL can be established.

Since WN and AL can be correlated with WP and WL2 under the same conditions, various multi-position linear arrays can be achieved by changing the placement position width in the multi-position linear array.

As shown in Figs. 15 to 18, the elements of the multi-position linear array 120 are mathematically combined, so that the WN arrangement positions (WN is a natural number of two or more) of the batch are successively overlapped at equal intervals in the horizontal direction. Linear arrays can form a multi-position linear array 120 of various structures.

FIG. 19 illustrates an embodiment having an array groove 311, or groove, to form a multi-position linear array structure 220 from a multi-position linear array 120.

According to the configuration of the multi-position linear array 120 described above, if the multi-position linear array is conceptually configured on the surface, and the arrangement groove 311 is provided so that each arrangement position 301 included in the multi-position linear array is partitioned. The multi-position linear array structure 220 can be achieved.

FIG. 20 shows an arrangement column 321 for forming a multi-position linear array structure 220 from a multi-position linear array 120. The arrangement positions 301 may be arranged at equal intervals so as to be continuously overlapped along the multi-position linear array center lines 122a and 122b to form the multi-position linear array 120, and each arrangement is arranged along the circumference of the multi-position linear array. Arrangement pillar 321 may be provided so that the position 301 is partitioned.

The array pillar center point 322 of FIG. 20 is positioned at the contact point of the overlapping center line 113 and the array circumference line 112, and each array pillar may have a contact with two adjacent arrangement positions 301.

Reducing to the description of FIGS. 15 to 20,

The multi-position array structure 210 according to the first embodiment of the present invention includes a structure called a multi-position linear array structure 220, and is made up of straight lines and curves including dotted lines of various forms by selective arrangement of the arrangement. You can implement an image.

The multi-position linear array structure 220 superimposes the arrangement position of the placement on the surface on the line to the multi-position linear array 120, the overlapping array is adjusted to the multi-position linear array equal spacing line 123 degree of overlap It can be adjusted, it is preferable to include a receiving portion 310 so that each arrangement position that the multi-position linear array 120 includes.

21 and 22 illustrate an embodiment in which the multi-position linear array 120 is expanded to form a multi-position planar array 130.

Referring to FIG. 21, three multi-position linear arrays c11 are repeated three times in the vertical direction 353 to form one multi-position plane array c10, and another multi-position linear array c12 is arranged in the vertical direction ( 353) is repeated three times to form another multi-position surface array (c20), and comprises two multi-position surface array (c10, c20) to form a wider multi-position surface array (c40).

For convenience of description, the two multi-position linear arrays c11 and c12 are formed on the multi-position linear array centerline 122a parallel to the transverse direction 352, but the two lines need not be parallel, and the multi-position linear The arrangement center line 122a may have various arrangement directions as long as it is not perpendicular to the horizontal direction 352.

22, two multi-position linear arrays c13 are repeated in the longitudinal direction 353 to form one multi-position plane array c30, and another multi-position linear array c12 is in the longitudinal direction 353. Repeated five times to form another multi-position planar array (c20), including the two multi-position planar array (c30, c20) to form a wider multi-position planar array (c50).

Referring to FIGS. 21 and 22, it can be seen that the multi-position plane array 130 including the multi-position linear arrays 120 may be formed in various ways.

23 and 24 are examples of partially enlarging the multi-position planar array 130 of FIGS. 21 and 22 and providing the array columns 321 in the partially enlarged view.

Referring to FIG. 23, four array columns c61, c62, c63, and c64 are illustrated in an enlarged view of the multi-position planar array c10 of FIG. 21.

As described above, any two arrangement positions 301 arranged in succession may have one virtual region b35. The virtual region b35 is an array circumference 112 circumscribed to two adjacent arrangement positions and a virtual region b35 divided by the two arrangement positions 301.

The plurality of multi-position linear arrays 120 may be repeated to form the multi-position plane array 130, and each of the multi-position linear arrays c11 may have respective array columns c61 and c62. The array columns c63 and c64 may be provided in common contact with two multi-position linear arrays c11 adjacent to each other in the longitudinal direction 353.

The array columns c63 and c64 which are in common contact with the two vertically adjacent multi-position linear arrays may be provided over two virtual regions b35 that are vertically adjacent to each other. It may have a contact point with a pair of arrangement position 301 partitioning the virtual area in b35). The array columns c63 and c64 in common contact with the two multi-position linear arrays may have four contact points with the arrangement positions 301.

Referring to FIG. 24, four arrangement columns c71, c72, c73, and c74 are illustrated in an enlarged view of the multi-position planar array c30 of FIG. 22.

Of the four array columns, two array columns (c73 and c74) are provided on the overlapping array line 113 to partition each of the multi-position linear array (c13), the other two array columns (c71, c72) Two adjacent multi-position linear arrays (c13, c13).

FIG. 25 shows an embodiment of the array column in the multi-position planar array structure 230 according to FIG.

FIG. 26 shows yet another embodiment of the array column in the multi-position planar array structure 230 according to FIG. 24.

Reducing to the description of FIGS. 21 to 26,

The multi-position array structure 210 according to the second embodiment of the present invention includes a structure called the multi-position planar array structure 230, and may implement various types of two-dimensional images by selectively arranging the arrangement. It may be suitable for the implementation of an image including a two-dimensional shape having a structure of straight lines and curves.

The multi-position plane array structure 230 includes a multi-position linear array 120 by repeating the arrangement positions of the arrangements on a line on the surface, and repeating the multi-position linear array 120. Further comprising, it is preferable to include a receiving portion so that each arrangement position that the multi-position planar array 130 includes.

27 to 30 illustrate a multi-position circular array structure as a third embodiment of the present invention.

FIG. 27 conceptually illustrates the components of the multi-position circular array 140 included in the multi-position circular array structure 240.

Referring to FIG. 27, a multi-position circular array 140 may be formed by continuously arranging an arrangement position 301 on a circumference (or a multi-position circular array centerline 142) on a surface.

A preferred embodiment of the multi-position circular array 140 may be to arrange the arrangement position 301 superimposed on the circumference and to be divided at equal intervals. In order to explain the preferred embodiment, FIG. 27 arranged six arrangement positions 301 and WP2 on the multi-position circular array centerline 142 forming a circle. The center of each placement location 301, WP2 may coincide with the vertex 145 of a regular polygon inscribed to the multi-position circular array centerline 142.

By arranging the arrangement positions 301 in the circumference at equal intervals, the arrangement of the overlapping positions means that the center points of the arrangement positions 301 constituting one multi-position circular arrangement are arranged at the same arrangement angle 143 on the circumference. Has meaning. Therefore, if the number of arrangement positions constituting one multi-position circular array 140 is RN (RN is a natural number), the number of vertices of the inscribed regular polygon is also RN.

If the placement position 301 is located at the vertex of the regular polygon that is inscribed, the angle formed by the center point of the adjacent pair of placement positions 301 and the multi-position circular array center point 141 is divided by the number of vertices of the regular polygon that inscribe 360. The following equation can be satisfied.

RN / 360 = array angle

Referring to FIG. 27, if the length of one side of the regular polygon inscribed in one multi-position circular array 140 is PL, adjacent arrangement positions 301 when the width WP of the arrangement position 301 is larger than PL ) Can be nested.

WP> PL

Referring to FIG. 27, in order to superimpose the arrangement positions 301 and WP2, the number RN of arrangement positions of the multi-position circular array is set to 7 or more, or the radius CR of the circular array center line is smaller than CR. Alternatively, the arrangement position WP3 having an arrangement position width larger than WP2 can be arranged.

Under the conditions shown in FIG. 27, if the number of arrangement positions 301 and WP2 is adjusted to 7 or more, or the arrangement positions 301 and WP2 are arranged in a regular polygon having more vertices, the degree of overlap can be adjusted. Can understand.

Multi-position circular array 140 is characterized in that it can be arranged in a number of different arrangement positions by adjusting the degree of overlap.

28 is an embodiment of a multi-position circular array 140.

In an embodiment of the multi-position circular array 140 in which the number RN of arrangement positions of the multi-position circular array is 24, the inscribed regular polygon may be a 24-angle. Each arrangement position 301 may have a name in the order of d01 to d24.

From the arrangement positions 301 of d01 to d24, a placement may be disposed only at an even position, or a placement may be disposed only at an odd position to implement a circular image. In addition, by placing the arrangements in the order of d01, d04, d07, d10, and d13, various images may be implemented such as a circular image including an arc formed by a dotted line.

FIG. 29 shows an example in which the multi-position circular array 140 of FIG. 28 is partially enlarged and an array column 321 is provided in the partially enlarged view.

Referring to FIG. 29, three array columns d51, d53, and d54 are illustrated in the multi-position circular array 140.

In the multi-position circular array 140, one end of the overlapping center line 113 may face the circular array center line 141.

The array column center points 322 and d51 of the array columns 321 and d51 may coincide with the contacts of the overlapping center line 113 and the array circumference line 112.

The array pillar center points 322 and d53 of the array columns 321 and d53 may be positioned on the overlapping center line 113 and may not coincide with the contacts of the array circumference line 112.

The array pillar center points 322 and d54 of the array pillars 321 and d54 may be positioned on the overlapping center line 113 and may not coincide with the contacts of the array circumference line 112.

Referring to FIG. 29, it will be appreciated that the multi-position circular array structure 240 may include various array columns 321 as the receiving portion 310.

FIG. 30 is an embodiment of a multi-position circular array structure 240 that includes an array column 321 to partition each arrangement position that the multi-position circular array 140 of FIG. 28 includes. The arrangement 331 is disposed to exemplify an image having a circle.

Reducing to the description of FIGS. 27 to 30,

The multi-position array structure 210 according to the third embodiment of the present invention includes a structure called a multi-position circular array structure 240, and circles and arcs implemented by various forms of points and lines by selective arrangement of the arrangement. An image including the shape of the can be implemented.

Multi-position circular array structure 210 includes a multi-position circular array 140 for arranging the arrangement position of the placement on the circumference superimposed, the overlapping arrangement to adjust the degree of overlap by adjusting the array angle (143) And it is preferable to include a receiving portion so that each arrangement position that the multi-position circular array 140 includes.

31 to 32 illustrate a multi-position disc array structure 250 as a fourth embodiment of the present invention.

31 conceptually illustrates the components of the multi-position disc array 150 included in the multi-position disc array structure 250.

Referring to FIG. 31, the arrangement position 301 is arranged on the circumference on the circumference (or the multi-position circular array centerline 142) continuously to form a multi-position circular array 140, and the multi-position circular array is concentric. The multi-position disc array 150 can be repeated.

In the embodiment of Figure 31, there are five multi-position circular array centerlines 142, each of which is concentric. The first multi-position circular array center line 142a is a multi-position circular array center line having no diameter. The multi-position circular array 140 may have a multi-position circular array centerline 142 smaller than one placement position width WP.

Five multi-position circular array centerlines in FIG. 31 are arranged at equal intervals from the circular array center point 141 for convenience of description. However, the plurality of multi-position circular arrays 140 constituting one multi-position disc array 150 may be arranged in concentric circles of different intervals so long as adjacent multi-position circular arrays do not overlap.

An example of the multi-positioned disc array 150 of FIG. 31 is composed of five multi-positioned circular arrays 140 consisting of placement positions 301 having the same placement position width WP, where each multi-positioned disc array is Each may have a different arrangement angle 143.

FIG. 32 illustrates an example in which the multi-position disc array structure 250 includes a groove (or an array groove 311) as the receiving portion 310 in the multi-position disc array 150 of FIG. 31.

The arrangement 331 may be selectively arranged to implement various two-dimensional images including a disk.

Reducing to the description of FIGS. 31 to 32,

The multi-position array structure 210 according to the fourth embodiment of the present invention includes a structure called a multi-position disc array structure 250, and includes a two-dimensional image including various circles and arcs in a selective arrangement of the arrangement. Can be implemented.

The multi-position disc array structure 250 arranges the arrangement position of the placement on the surface so as to be arranged at equal intervals on the circumference so as to overlap the multi-position circle array 140, and repeats the multi-position circle array 140 concentrically to the multi-position It is preferable that the disk array 150 includes a receiving unit so that each arrangement position included in the multi-position disk array 150 is partitioned.

33 to 34 show an embodiment of the multi-position array structure display device 270 of the present invention.

33 is a perspective view and a front view of the multi-position array structure display device 270 that further includes a power supply and an electrode in the multi-position array structure 210 so that the light source can be disposed as a placement.

The accommodation unit 310 is provided to accommodate the light source arrangements 331p and 331q formed of a light source such as an LED, and further includes electrodes e21 and e22 in the accommodation unit 310. In the electrodes e21 and e22, the first electrode e21 is positioned on the side of the array groove 311, and the second electrode e22 is positioned on the bottom surface of the array groove 311, so that the light source arrays 331p and 331q are disposed. It may be a corresponding electrical contact.

It also includes a power source (e10) for supplying power to the light source arrangements (331p, 331q). Additionally, a separate control unit (not shown) may be further included for controlling the light source arrangement to be flickered.

34 is a diagram for illustrating the cross-sectional view of FIG. 33.

Referring to FIG. 34, the multi-position array structure display device 270 makes contact with the bottom surface of the electrode e22 and the light source arrangements 331p and 331q having contacts with the bottom surfaces of the coupling portions of the light source arrangements 331p and 331q. The electrode e21 may be included, and the two electrodes e21 and e22 may be configured on the substrate e11.

The multi-position array structure display device 270 according to the fifth embodiment of the present invention may further include a power supply unit and an electrode in the multi-position array structure 210, and implement a light emitting image by arranging a light source as a batch. have.

[Description of the code]

110: multi-position array

112: array circumference

113: overlap centerline

120: multi-position linear array

122: multi-position linear array centerline

123: multi-position linear array equal spacing

130: multi-position planar array

140: multi-position circular array

141: multi-position circular array center point

142: multi-position circular array center line

143: array angle

144: inscribed regular polygon

145: vertex of an inscribed regular polygon

146: diameter of circular array center line

150: multi-position disc array

210: multi-position array structure

220: multi-position linear array structure

230: multi-position planar array structure

240: multi-position circular array structure

250: multi-position disc array structure

270: multi-position array display device

301 (301a, 301b, 301c, 301d, 301f, 301g, 301h, 301k): arrangement position

302: placement location center point

310: receiving part

311: Array groove

321 array column

322 center point of array column

331 (331a, 331b, 331c, 331d, 331f, 331g, 331h, 331k, 331m): batch

331p, 331q: light source arrangement

351 surface

352: horizontal direction

353: portrait orientation

Claims (11)

1. An arrangement structure including a plurality of arrangement positions, in which a conceptual arrangement position of a placement is superimposed on a surface and provided with a receiving portion so as to define each of the nested arrangement positions, wherein the placement positions can be selectively arranged.

   A multi-position linear array structure in which a plurality of linear positions are arranged by overlapping the arrangement positions of the arrangements on a line, and the receiving unit is partitioned so that each arrangement position included in the multi-position linear array is divided;

   A multi-position planar array structure in which a multi-position plane array is repeated to repeat the multi-position linear array, and a receiving unit is provided to partition each arrangement position of the multi-position plane array;

   A multi-position circular array structure in which the arrangement positions of the arrangements are superimposed on the circumference and arranged in a multi-position circular array, and the receiving portion is partitioned so that each arrangement position included in the multi-position circular array is partitioned; And

   A multi-position disc array structure in which a multi-position disc array is arranged in a concentric circle to repeat the multi-position disc array, and a receiving portion is provided to partition each arrangement position of the multi-position disc array;

   In the group consisting of, the array structure, characterized in that configured to be selected, corresponding to each or a combination of linear and planar, circular and disk-shaped images,

   Multi-position array structure that lays out layouts and implements images.
2. The method of claim 1, wherein the multi-position linear array,

   A multi-position array structure for realizing an image by arranging arrangements, characterized in that the arrangement positions on the surface are arranged in a line at equal intervals in the horizontal direction.
3. The method of claim 1, wherein the multi-position circular array,

   A multi-position array structure for realizing an image by arranging a layout, wherein the arrangement is superimposed so as to divide the placement position on the surface at equal intervals.
4. The method according to any one of claims 1 to 3,

   Wherein the receiving portion is characterized in that having a groove in the arrangement position so that the arrangement position is partitioned, multi-position array structure for implementing the image by placing the arrangement.
5. The method according to any one of claims 1 to 3,

   Wherein the receiving portion is characterized in that the arrangement position is arranged so as to project the array column around the arrangement position, multi-position array structure to implement the image by placing the arrangement.
6. The method according to any one of claims 1 to 3,

   The arrangement position is characterized in that the circular, multi-position array structure for implementing the image by placing the arrangement.
7. The method according to any one of claims 1 to 3,

   The arrangement position is characterized in that the polygon, the multi-position array structure for implementing the image by placing the arrangement.
8. The method according to any one of claims 1 to 3,

   The overlapping arrangement is a multi-position array structure for implementing the image by arranging the arrangement, characterized in that for adjusting the number of placement positions by adjusting the degree of overlap.
9. The method according to any one of claims 1 to 3,

   The arrangement is characterized in that the display portion and the coupling portion is asymmetrical, multi-position array structure to arrange the arrangement to implement the image.
10. A multi-position array structure display device including a power supply unit and an electrode in the multi-position array structure according to any one of claims 1 to 3, and disposing a light source arrangement to display an image.
11. The method of claim 10,

    The light source arrangement is characterized in that the LED, multi-position array structure display device for implementing the image by placing the light source arrangement.

Images