KR20200014710A - Space separating structure - Google Patents

Abstract

The present invention provides a space separating structure comprising: at least one side unit configured to separate a space into one side space and a first area; and at least one other side unit configured to separate the space into the other space and a second area. The one side unit and the other side unit are alternately arranged to have an overlapped portion with each other for the first area and the second area to be connected to each other through a common area provided by the overlapped portion. Moreover, the one side unit and the other side unit which are alternately arranged divide the one side space from the other side space. In addition, the second area connected to the one side space, the common area, and the first area connected to the other side space form a route of objects or waves between the one side space and the other side space.

Description

Space Separation Structure {SPACE SEPARATING STRUCTURE}

The present invention relates to a space separation structure.

The present invention relates to a space separating structure, and when separating spaces, it is necessary to decide whether to block or allow the exchange between the separated spaces. As an example of a building that divides a space into an interior space and an exterior space, the walls of the building block the exchange of the interior space with the exterior space, while the windows or doors of the building provide a passageway between the interior space and the exterior space. Furthermore, the user can appropriately control the exchange between the internal space and the external space through the opening and closing of the window or the door as needed. For example, a user may close a window on a cold winter night and leave the window open on a hot summer night.

However, as can be seen from FIG. 1, conventional windows do not provide sufficient control to the user.

1 is a side cross-sectional view conceptually illustrating the structure of a window according to the prior art. FIG. 1 (a) shows when the window 600 is closed, and FIG. 1 (b) shows when the window 600 is opened.

These drawings simplify the structure of the window for ease of explanation and understanding. For example, the upper and lower window frames and the walls 510 and 520 are illustrated without being distinguished, and the thickness, shape, and number of the windows 600 are not specified. In addition, the ground 700 represents all structures that can change the direction after the impact of an object or wave, such as the ground, balcony floor, windowsill.

(A) of the figure shows that the closed window 600 blocks both an object or wave in the x direction and an object or wave in the y direction. For example, rain that hits the ground 700 as well as rain that hits the window 600 directly is all blocked by the window 600. However, the closed window 600 has a problem of blocking the flow of air.

On the other hand, as shown in (b) of the drawing, when the window 600 is open, there is a problem that not only the air but also the ratio of the direct and indirect directions (x, y) is not blocked.

As such, the conventional window does not provide sufficient control over the exchange between the inner space and the outer space, which may cause inconvenience and damage to the user.

For example, the user may go out with the window 600 open and be damaged by suddenly pouring rain. In addition, the user may experience inconvenience when it rains even if the user wants to open the window 600 wide due to the need for ventilation or hot weather. This is because the damage when the room is wet can be great. For example, if the wallpaper or floor is not properly dried, mold may develop, and the loss of valuables may be greater.

Although air and rainwater have been described as an example, conventional windows do not provide sufficient control over the flow of waves with other objects, which may explain the inconvenience and many techniques have been developed to solve such problems. It will not be necessary. For example, a user may attach a light blocking film or a sunscreen film to the window 600.

However, these prior arts still do not provide sufficient control. For example, the light blocking film or the UV blocking film does not block light or ultraviolet rays when the window 600 is open, no matter how good the blocking performance thereof is. Conventional window coverings such as blinds and curtains do not effectively block rain and wind when the window 600 is opened. In addition, these window screens have a disadvantage in that they must sacrifice breathability to block light or ultraviolet rays.

Therefore, it is necessary to develop a new structure that can more effectively control the entry and exit of objects (eg, air and water) and waves (eg, visible light and ultraviolet light) between the internal space and the external space regardless of whether the window 600 is opened or closed. Do. In addition, although the window has been described as an example, the new structure described herein is not limited thereto, and refers to a structure capable of controlling objects and wave exchanges between any indoor and outdoor separated spaces.

In connection with the present invention, Korean Patent Document 20-2011-0000360 ("Partition") discloses a partition for providing an electrical outlet and a wire receiving portion.

In addition, Korean Patent Document 20-0416668 ("screen with a lighting device") discloses a screen with a light.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problem, and an object thereof is to provide a space separation structure capable of effectively controlling the entry and exit of objects or waves between separated spaces.

Space separation structure according to the first aspect of the present invention for achieving the above object is at least one side unit for separating the space into one space and the first region; At least one other unit separating the space into the other space and the second area, wherein the one unit and the other unit are alternately disposed so that there is a portion overlapping each other, and the common region is provided by the overlapping portion. The first area and the second area are connected to each other through, and the alternately arranged one side unit and the other unit separate the one side space and the other side space, the second area connected to the one side space, the common An area, wherein the first area connected to the other space forms a path of an object or a wave between the one space and the other space.

The present invention achieves the effect of effectively controlling the entry and exit of objects or waves between the separated spaces in the space separating structure.

In particular, it provides a selective blocking structure that blocks certain objects or waves while at the same time providing a path to another particular object or wave. This selective blocking structure allows only the right amount of objects or waves to be provided with passages.

Moreover, this effect is achieved with a very simple structure. There is no need for complicated structures, expensive materials, or troublesome operating procedures. Therefore, the production cost of the manufacturer and the installation and use cost of the user are low.

It is also freely removable, easy to install and expand, and flexible to change configurations as needed. In particular, this not only allows the user to dynamically control the flow of objects or waves between spaces as needed, but also provides the user with an opportunity to customize the structure according to his aesthetic preference. This is an advantage that can give users the satisfaction of making their own things. In addition, there is an advantage that the supplier can easily diversify the product and diversify the market.

It also provides an indirect path through which objects or waves can pass between the separated spaces. Since the indirect path may be used for various purposes, the space separation structure according to the embodiment of the present invention has an advantage of wide application range.

1 is a side cross-sectional view conceptually illustrating the structure of a window according to the prior art.
Figure 2 shows a side cross-sectional view conceptually illustrating the structure of a space separation structure according to an embodiment of the present invention.
Figure 3 shows a planar cross-sectional view conceptually illustrating the structure of a space separation structure according to an embodiment of the present invention.
4 illustrates an embodiment structure of a space separation structure according to an embodiment of the present invention.
5 conceptually illustrates a side view of a space separation structure according to an embodiment of the present invention.
6 illustrates an embodiment of a space separating structure driving unit according to an embodiment of the present invention.
Figure 7 illustrates an embodiment of a space separating structure concealment means according to an embodiment of the present invention.
8 shows an embodiment of a space separating structure concealment means according to an embodiment of the present invention.
Figure 9 illustrates an embodiment viewed from the front of the spatial separation structure connecting portion according to an embodiment of the present invention.
Figure 10 illustrates an embodiment viewed from the side of the spatial separation structure connecting portion according to an embodiment of the present invention.
FIG. 11 illustrates an embodiment viewed from the side of a space separating structure connection unit according to an embodiment of the present invention.
12 conceptually illustrates a spatial separation structure and connections according to one embodiment of the invention.

DETAILED DESCRIPTION Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention. As those skilled in the art would realize, the described embodiments may be modified in various different ways, all without departing from the spirit or scope of the present invention. In the drawings, parts irrelevant to the description are omitted in order to clearly describe the present invention, and like reference numerals designate like parts throughout the specification.

Throughout the specification, when a part is "connected" to another part, it includes not only "directly connected" but also "electrically connected" with another element in between. . In addition, when a part is said to "include" a certain component, this means that it may further include other components, except to exclude other components unless otherwise stated.

1, the development of a structure that can effectively control the entry and exit of the separated interspace objects (eg, air, water) and waves (eg, visible light and ultraviolet light) has been described. It will be easily understood that the scope of the present invention is not limited thereto, but it will be easy to explain and understand in comparison with the window described in FIG. 1, so that the structure and operation of the present invention when installed or attached to the window will be described. Explain first.

First, through the comparison of Fig. 1 and Fig. 2 and Fig. 3- (a), how the space separation structure according to an embodiment of the present invention blocks a specific object or wave, and then through Fig. 3- (b), We will see how a spatial separation structure according to one embodiment of the present invention provides an indirect passage for a particular object or wave.

In these drawings, the structure of the window is the same as that described in FIG. For example, the ground 700 does not simply refer to the ground itself, but refers to an object or any object that waves can bump and change direction.

2 is a side cross-sectional view conceptually illustrating a structure of a space separation structure according to an embodiment of the present invention.

If the spatial separation structure 10 according to an embodiment of the present invention is used in the window of FIG. 1, even when the window 600 is open, unwanted objects (eg, water) as described in FIG. Explain that it can be blocked from entering the space.

The space separation structure 10 according to an embodiment of the present invention has a structure in which one side unit 100 and the other side unit 200 are alternately disposed. In the example of the figure, one side unit 100 is located in the outer space side, the other unit 200 is located in the inner space side. The one side unit 100 and the other side unit 200 may be coupled to each other through the unit coupling unit 300, and may be attached or installed to another structure (eg, a window frame or a wall) through the connection unit 400. The connector 400 may also be configured to serve as a framework for providing tightness and stability to the spatial separation structure 10 according to one embodiment of the invention. Details of this specific configuration will be described later after describing the concept.

The drawing shows an example in which unwanted objects or waves enter the inner space from the x direction and the y direction of the outer space as shown in FIG. 1. As shown, the spatial separation structure 10 in accordance with one embodiment of the present invention blocks such unwanted objects or waves as the window 600 without the window 600. The drawing shows only that the object or the wave is blocked by one side unit 100 located on the outer space side, but this is for convenience of illustration, it is also blocked by the other unit 200 located on the inner space side. Can be. For example, both the direct rain (x) and the rain water (y) splashed after hitting the ground 700 both the one unit 100 and the other unit 200 of the spatial separation structure 10 according to an embodiment of the present invention. Is blocked by) and cannot enter the room. To help understand this, look at Figure 3 (a) shown at another point in time.

Figure 3 shows a planar cross-sectional view conceptually illustrating the structure of a space separation structure according to an embodiment of the present invention. 3 (a) shows the principle of blocking unwanted objects, and FIG. 3 (b) shows the principle of providing a passage to a desired object.

As shown in the figure, one unit unit 100 located on the outer space side and the other unit 200 located on the inner space side are alternately arranged such that there are overlapping portions (100A and 100B, respectively).

Referring first to Figure 3- (a), the flow of unwanted objects (e.g., rain, snow, fallen leaves, dust, etc.) or waves (e.g., visible light, ultraviolet light, etc.) shown by x and y in Figures 1 and 2 In Fig. 3- (a) it is expressed by z. If x and y were to pay attention to the angle of entry when the window was viewed from the side, and to consider changing the direction by hitting another object accordingly, z is the angle of entry when the window was viewed from above.

As shown, the flow z is blocked by one unit 100 and the other unit 200 whether entering the window vertically (first and second z) or at an angle (third z).

Take rainwater as an example. 3 (a) together with FIG. 2, when rain hits one unit 100 located on the outer space side, it flows down the outer surface of one unit 100 and falls into the outer space, thus entering the inner space. You can easily understand that you can't. The same applies to the case where the rainwater hits the other unit 200 located on the inner space side. The rainwater that hits flows down the outer surface of the other unit 200 and falls into the outer space. Some rainwater hitting the outer surface of the other side unit 200 may splash to the inner surface of the one side unit 100, but such rainwater also flows down the inner surface of the one side unit 100 and falls into the outer space. Even if it bounces from the inner surface of the one side unit 100 to the outer surface of the other side unit 200 again through the described process will eventually fall into the outer space. Therefore, the rainwater is blocked from entering the interior space no matter what.

Here, the outer surface of the one side unit 100 or the other side unit 200 all refer to the surface facing the outer space side, the inner surface refers to the surface all located on the inner space side. More generally, one side of the one side unit 100 and one side of the other side unit 200 both face the one side space side, and the other side of one side unit and the other side of the other side unit 200 all the other side space Refers to the side facing the side. Since it is explained when it is used for a window, it is easy to divide the space into an inner space and an outer space, so the outer surface of each unit is referred to as an inner surface and an outer surface.

Although the window 600 is illustrated in FIG. 1 as a line rather than an object having a thickness and an inner surface and an outer surface, the shapes of one side unit 100 and the other side unit 200 are simply illustrated as lines in FIGS. 2 and 3. It should be noted that this is merely shown for the sake of simplicity. It will be readily understood that the inner and outer surfaces of the one side unit 100 and the inner and outer surfaces of the other unit 200 may have different shapes.

In addition, the rain water that hits the one side unit 100 or the other unit 200 flows down into the inner surface of the other one unit 100 or the other side unit 200 is not flowing into the inner space is because the upper and lower units This is because they are coupled through the unit coupling part 300. Detailed description thereof will be described later like other structures.

Referring now to FIG. 3- (b), the flow of an object or wave (eg, air or wind) desired to enter and exit, as opposed to x, y, and z, is shown in FIG.

In Figure 3 (a) it was seen that the rainwater is blocked by hitting the unit 100 and the other unit 200. On the other hand, since air has a different property from water, even though it collides with one side unit 100 and the other unit 200, air may flow into the inner space through a path as shown in FIG. It is also free of air to be discharged to the outside space.

The unwanted object is blocked due to the structure in which one side unit 100 and the other unit 200 are alternately arranged, and the air, which is a desired object, is alternately arranged when the one side unit 100 and the other unit 200 are alternately arranged. Entry and exit is possible due to the structure in which the overlapping portions 100A and 200A are arranged.

In more detail, one side unit 100 that separates a space into one side (eg, an outer space) and a first region, and the other side unit 200 that separates the space into another side (eg, an inner space) and a second region Due to this alternately arranged structure, one space and the other space are separated from each other, and water, which is an unwanted object, cannot be moved between one space and the other space.

On the other hand, since the one side unit 100 and the other side unit 200 are alternately arranged so that there are overlapping portions 100A and 200A, the first region through the common region provided by these overlapping portions 100A and 200A. And the second region are connected to each other, which allows air to travel in the order of one space> the second region connected to one space> the common region> the first region connected to the other space> the other space, or vice versa. Between the space and the other space, the desired object, air, can come and go.

For example, the outside air is connected to the outside space through a second area connected to the outside space, that is, a gap area without one unit 100 (two gaps shown at the top side in FIG. 3- (b)). Space on the outer surface side of the other unit 200), but may not directly advance to the internal space because the other unit 200 is soon met. However, this air is again connected to the inner space through the first area connected to the inner space, that is, the gap area without the other unit 200 (three gaps shown at the lower side in FIG. 3- (b)). It is possible to enter the space located on the inner surface side of 100), so it is not impossible to advance to the interior space.

This is possible because of the structure in which the second region and the first region have a common region (a space located on the inner surface side of one unit 100 and a space located on the outer surface side of the other unit 200 at the same time). As described above, the common area is an area that can be secured by overlapping and arranging one side unit 100 and another side unit 200.

Through the indirect passages, objects that want to enter and exit smoothly can be passed while preventing unwanted objects from passing through the separated spaces. In addition, it is also possible to prevent the passage of too much of a desired object. For example, you may want air in, but not too strong wind. In this case, the space separation structure 10 according to an embodiment of the present invention prevents a flow of wind or strong air from directly moving from one space to the other space or in the reverse direction, and separates the space separated through only the indirect path described above. Accessibility meets these requirements.

This indirect passage can also be used for other purposes. For example, the spatial separation structure 10 according to an embodiment of the present invention may be used for a diffuser of light or indirect lighting. The space separating structure 10 according to an embodiment of the present invention divides the space into one space having a light source and the other space supplied with light from the light source, but the light is separated from one space to the other space only through the indirect passage described above. To be supplied, the light is subjected to a process that is reflected back to one side unit 100 and the other side unit 200. Therefore, the spatial separation structure 10 according to an embodiment of the present invention has an effect of softly diffusing and softening the light supplied from the light source, and thus may be used in lighting facilities such as lamp shades. In particular, LED lighting, which is recently attracting attention, has a disadvantage in that the light source has a strong characteristic of straight light having a strong straightness, and the spatial separation structure 10 according to an embodiment of the present invention may be used to compensate for this disadvantage. Space separation structure 10 according to an embodiment of the present invention can be used by overlapping a plurality, this embodiment may be particularly effective when used as a light diffuser.

As another example, the spatial separation structure 10 according to an embodiment of the present invention may be used as a space partition having a light supply function. Conventional space partitions, screens, etc. provide a function to separate the space and block the view, but does not provide a function to supply light between the separated space. Therefore, when using this prior art, it should be noted that each compartment has a separate light source or a dark compartment. However, the spatial separation structure 10 according to an embodiment of the present invention blocks the field of view to provide independence between the separated spaces, and light is supplied to the other compartment even if only one light source is provided. Moreover, this light has the advantage of light diffused through the indirect path as described above. Therefore, the spatial separation structure 10 according to an embodiment of the present invention can satisfy aesthetic elements when used as a space partition. For reference, this aesthetic element can be further maximized because the spatial separation structure 10 according to an embodiment of the present invention may have various shapes in which planes and curved surfaces are mixed, unlike conventional space partitions or screens.

That is, the spatial separation structure 10 according to an embodiment of the present invention may be used to focus on selective blocking of an object or wave, or may be used to provide an indirect passage providing function of an object or wave. This function is used between the separated spaces, the space separating structure 10 according to an embodiment of the present invention may separate the space alone or with other structures, installed in a space separated by other structures such as windows or doors Or may be attached and used. At this time, there is no limitation in the space separated by the space separation structure 10 according to an embodiment of the present invention. For example, the space separating structure 10 according to one embodiment of the present invention can be used to re-separate a small space separated by another structure called a drawer. It has the advantage of reducing moisture damage to the contents of each compartment (eg clothes, food, etc.).

As can be seen from the above description and the drawings, the spatial separation structure 10 according to an embodiment of the present invention requires a complicated structure, expensive materials, cumbersome operating procedures, etc. to obtain the above-described selective blocking and indirect passage providing effect. Do not For example, the spatial separation structure 10 according to an embodiment of the present invention does not require expensive filters or new materials. There is also no need for mechanisms or electrical circuits to drive the structure 10 and no user input is required for operation. This not only lowers production and use costs, but can also provide user convenience and psychological stability.

For example, when the user suddenly rains when going out as described in FIG. 1, furthermore, even when the wind blows and rains, or when there is a lot of rain, the user can be installed or attached to the window thanks to the space separating structure 10. You do not need to take any action, and when you return from the outside, your room is ventilated with cool, fresh air, without being polluted by rain, strong winds, or soiled by windy dust. You can be assured that you will not have to be as insecure as usual or have the inconvenience of hurrying back only to close the window 600.

An example of the detailed structure and some design considerations of each component of the spatial separation structure 10 will now be described with one embodiment shown in FIG.

Through this description, it can be seen that the spatial separation structure 10 according to an embodiment of the present invention improves user convenience by providing flexibility and determinism while obtaining various effects with only a simple structure as described above. will be.

It should be noted that the examples described in this specification, and in particular, the following examples, are all for illustrative purposes, and the scope of the present invention is not limited thereto.

4 illustrates an embodiment structure of a space separation structure according to an embodiment of the present invention.

The first and second drawings of FIG. 4 show an embodiment of one side unit 100 and the other side unit 200, respectively, and the third figure shows a portion 100A that overlaps one side unit 100 and the other side unit 200. 200A) shows alternately arranged embodiments. This is a view for explaining the structure in one embodiment, like the other drawings are shown as simple as possible for convenience of explanation and understanding. For example, the shape of the inner surface and the outer surface of each unit may be different for convenience.

The figure is a view seen from the other space among the space divided into one space (for example, the outer space) and the other space (for example, the interior space). That is, only the inner surface of each of the one side unit 100 and the other side unit 200, that is, the outer surface located on the other side of the space is shown. In the following description, for convenience, one space will be referred to as an outdoor or external space and the other space as an indoor or internal space. This is because it will be easy to assume that the illustrated embodiment is installed in the window.

In the illustrated embodiment, one side unit 100 has a convex shape toward the outer space, the other unit 200 toward the inner space. In such an embodiment, the size of an interspace passage consisting of a first region, a common region, and a second region can be increased. Thus, for example, when one wants to increase the amount of ventilation and allow air to flow well, one or both of the unit 100 and the other unit 200 can be convex. On the other hand, excessively convex, there may be some disadvantages, such as inconvenient when opening and closing the window 600 when the space separating structure 10 occupies too much space or is installed or attached to the window. Therefore, the convex shape and the degree can be adjusted to configure the spatial separation structure 10 that is optimal for the purpose and environment of use. For example, you may use a non-convex or slightly convex shape when you want to ventilate in an environment where the wind is too strong, but you want to prevent too much wind from entering the room.

The drawing shows an embodiment in which all one side unit 100 and the other side unit 200 have the same shape and degree of convexity, but the shape and degree of convexity of each unit may be different. In particular, FIG. 2 illustrates an embodiment in which one side unit 100 is convex than another side unit 200.

2 is different from the embodiment of FIG. 4 in the form of convexity. 4 uses two planes, while FIG. 2 uses one curved surface. These drawings are only examples for showing that various configurations are possible, but are not limited thereto. For example, the two planes of FIG. 4 have the same size and shape and are folded at the center, but if necessary, the top surface is longer than the bottom surface, so that the folded line is biased downward or vice versa. . That is, there are no limitations on the number of folded lines (e.g., zero, numerous), position, or direction. For example, more planes may be used, or a combination of planes and curved surfaces may be used. Alternatively, the one side unit 100 and the other side unit 200 may be positioned on a plane parallel to each other.

The direction of convexity is also not limited to the embodiment of FIGS. 2 and 4. Not only can be convex in the opposite direction to the drawing (concave in the direction of the drawing), the overall shape can be convex, but in a detailed structure can be convex and concave to have the form of embossing. It may also include a perforated or perforated part in a detailed structure.

That is, the inner surface and the outer surface of one side unit 100 and the other side unit 200 may each have a variety of shapes configured using one or more planes or curved surfaces, or a combination thereof, which is also one of the elements selected according to needs. . For example, when the space separating structure 10 wants to block the coming and going of water between the separated spaces, the entire structure is convex but vertically concave lines on the outer surface of one unit 100 or the other unit 200 in detail. These concave shapes could serve as waterways that flow down when water is hit.

Furthermore, the drawing shows that when one side unit 100 and the other unit 200 is combined, an opening that can be used as a passage of air can be formed, but on the contrary, a portion where the opening is not formed is formed on one side unit 100. And it will be readily understood that it may be defined as the other side unit 200. That is, the spatial separation structure 10 according to an embodiment of the present invention also has the advantage of freeing the point of view of the manufacturing, the manufacturer combines the entire portion according to their needs, such as cost, efficiency, aesthetics, etc. In addition to creating, you can also choose to remove parts from the whole. For example, manufacturers benefit from the fact that similar designs can be manufactured both in a combined and in a removed manner to supply both high and low cost products simultaneously.

In addition, the manufacturer may further provide a means for the user to change one or more factors affecting the flow of the object and the wave, such as the shape and size of the one side unit 100 and the other unit 200, the size of the opening, more Furthermore, the high-end products and the low-end products may be more variously provided depending on whether the control means are provided. For example, the user can supply a product that can control the convexity of one unit 100, the other unit 200, or both at a higher cost, and the transparency of the material to be described soon or without the above function. It will be able to supply more expensive products that can control. That is, since the spatial separation structure 10 according to an embodiment of the present invention may be configured in various ways, the user may have a variety of options, and the supplier may have an opportunity to more easily diversify the market. .

It is not limited to structure and function. For example, various types of structures of each unit of the space separation structure 10 according to an embodiment of the present invention may be composed of one or more materials, and are not limited by materials.

For example, the detailed structure of each unit may include a reinforcing structure to increase the durability and lifespan, for example, a frame formed at the edge of the unit to prevent the unit from being damaged by the wind. The unit may be made of the same material or different materials.

As another example, different materials may be used for different layers of each unit.

For example, in addition to the above-described function of using the space separation structure 10 according to an embodiment of the present invention for the window, air and wind, while preventing the inflow of rain or snow indoors without the window 600, You do not want to be disturbed by the view, such as when you use curtains or blinds, but you want to block UV rays from entering the room. In summer, you prevent outdoor heat from entering the room. Consider a situation where you want insulation to prevent leakage into this room.

In order to be unobtrusive, you can use a material that can be transparent, translucent, or transparent as the base material for each unit. For example, plastics, glass, etc., which have high transparency, can be candidates for the base material of each unit since they are transparent and do not pass water.

Next, in order to block UV rays, it is possible to process the base material itself to block UV rays, but it is cheaper to maintain and add a layer having the corresponding function such as applying UV blocking ink or adding UV blocking film. It may be easy to change the maintenance or use technology or add functionality. For example, the use of a film has the advantage of being able to use a film that is cheap at first but has a low blocking rate and a short lifespan, and then changes to a film having a higher blocking rate, longer life, and other functions such as scattering prevention.

In this case, as described above, the supplier may supply the product using the material which can change transparently, that is, change the visible ray blocking rate at a higher price. In addition, products made of materials that can change the UV blocking rate can be supplied at a higher price.

The above description is merely an example, and the structure and material for providing the view and the structure and material for blocking visible or ultraviolet rays are not limited thereto (some additional examples will be described later for explanation). Similarly, the thermal insulation function can also be achieved by adding another layer, such as an air layer, but this is also for illustrative purposes only and is not limited thereto.

In this case, the layers of each unit may be formed only in part of the total area. For example, forming an air layer in several small spaces, such as an air cap, may be cheaper and more efficient than forming it in one large space. Alternatively, these layers may be configured differently for each unit. That is, each unit may be configured differently in material, shape, structure, and size.

For example, the outer surface of all one side unit 100 can be added to the light-shielding layer that is not in the other unit 200, or in a pattern such as alternately skipping without distinction between the one side unit 100 and the other side unit 200. The light blocking layer may be added only to the selected unit according to or according to an arbitrary selection.

Such a flexible configuration has an advantage that, for example, the degree of shading can be easily adjusted as necessary during use. For example, it is possible to remove the shading layer from all units in winter, and increase the number of units to which the shading layer is attached as the summer approaches. Alternatively, you can reduce shading in the morning and increase it during the day.

To this end, the spatial separation structure 10 according to an embodiment of the present invention has an additional structure that makes it easy to attach or detach a light shielding layer to one or more units, or the light shielding layer is rolled up or rolled up or rotated by the angle having the least light shielding effect. Both may include structures.

As such, the spatial separation structure 10 according to the embodiment of the present invention may further include additional structures as necessary. For example, it may further include a structure that can dynamically adjust the convexity of each unit as described above as needed.

In addition, the space separation structure 10 according to an embodiment of the present invention may be configured to be easily attached or detached to each unit itself or may be configured to be flexible to facilitate expansion. For example, the spatial separation structure 10 according to an embodiment of the present invention may be used to fold or roll all or part of the one or more units themselves, adjust the length, rotate, move, detach or change the curvature. It may further provide one or more means to apply deformation control. This gives the user additional control and aesthetics for objects and waves.

For example, the user can use the spatial separation structure 10 only at the bottom of the window and then use the entire window. Alternatively, you can use smaller units at the bottom of the window and larger units at the top of the window. Or you can use some of the units you used for a large door in a small window. Of course, it is also possible to provide a structure in which the number of units or the size of the entire structure is fixed and cannot be changed. Such a configuration can reduce costs due to the inflexibility and the extensibility, but can be manufactured all at once, and it is easier to make the whole structure more robust.

As another example, a user may customize one or more units by replacing them with units having different characteristics such as different designs, different colors, different sizes, different materials, and the like to customize their aesthetic preferences. Using color as an example, assuming that the user installs his space separating structure 10 in a window but wants to make it look white in the outdoors and shape it in the shape of a national flag, the user can use the white, black, blue, and red systems. Will combine their units to create their own spatial separation structure (10), and you will feel satisfied that you design your own objects and make them your own. Plus, it's easy to redesign whenever you need it. This is an advantage of keeping the user easily disgusted. In addition, the user needs a new colored unit and is more likely to buy more units, allowing the supplier to retain loyal customers for longer.

Furthermore, this can be achieved while better controlling static or dynamic alternating currents and waves between the spaces separated by the space separation structure 10 according to one embodiment of the invention. To do this, the user may purchase units of different materials, even with the same color and same design. This further reinforces the aforementioned advantages, both from the user's point of view and from the supplier's point of view.

In addition, the spatial separation structure 10 according to an embodiment of the present invention may further provide one or more means capable of controlling deformation in addition to the structure within the unit and the unit itself as described above. . That is, the spatial separation structure 10 according to the embodiment of the present invention may conceptually think of a fractal structure. Deformation control means may be further provided for each layer of the structure. However, the deformation control means that can be provided for each layer are independent of each other. For example, the whole structure 10 is provided with a control means which can be rolled up like a conventional roll screen (provided with one), and the control means and curvatures that can be folded or unfolded in the horizontal direction in each unit 100, 200 ( Control means for changing the degree of convexity) are provided (provided with two), and a light-shielding layer (not shown), which is an additional structure of one side unit 100, is provided with detachable control means (provided with one), The air layer (not shown), which is an additional structure of the other unit 200, may be configured such that no control means is provided (provided 0). Of course, this is only an example for description, and the configuration is not limited thereto.

It should also be noted that the deformation control in each layer is not limited to the example described herein.

The supplier can apply one or more of the prior art to the deformation control means of each of these layers. For example, the user can fold, roll or detach the space separating structure 10. Since this is also a function of window curtains such as curtains, feet, and blinds, a detailed description of the control function itself is omitted. However, there is a point to consider. As an example, for example, when the space separating structure 10 according to an embodiment of the present invention is installed in a window and is desired to be set to one side as a conventional window screen, if necessary, it is positioned below the window rather than the top of the window. It will generally be better to let it go. For example, the user may leave the top of the window empty to ensure viewing and breathing, while at the bottom of the window, the space separation structure 10 may block some or all of the structure 10 to prevent unwanted objects and waves, such as rainwater. You will want a means to fold or roll up, and you will want to maintain the openings so that aeration can be secured at the bottom of the window as well. However, this depends on the situation and needs and is not limited thereto. Deformation control means for the space separation structure 10 according to an embodiment of the present invention is so diverse that it can not be described all the drawings and detailed description for each, but the prior art required the space separation structure 10 It is merely an example to show that the deformation control means can be provided by applying to the. Of course, the present invention is different from structures such as conventional window screens, conventional partitions, screens, etc., so that there are control means that cannot be provided simply by combining the conventional technology. However, since the details of each of the deformation control means is outside the scope of the present specification, it will be described later in another specification.

In addition, the space separation structure 10 according to an embodiment of the present invention may be attached or detachably attached to another structure through the connection unit 400 as described above, and applies the prior art as in the above-described deformation control means. Or use new technology. Here, some examples of applying the prior art will be described. Here, the connection part 400 is used to refer to one or more components attached or separated from each other for installing or attaching the space separation structure 10 to another structure or space, and as described above, only the connection structure itself is used. It may also include a framework of the entire structure (10). Thus, the structure for installing or attaching the space separation structure 10 can also be configured in various ways.

For example, when installing in a window, the space separating structure 10 according to an embodiment of the present invention may be placed on the floor near the window using a stand like a conventional screen or a space partition. Or it may be installed or attached to the wall near the window, various structures, such as the method used in conventional window shades such as curtains, blinds, roll screens, sunshades, etc. may be used for such installation or attachment. The use of a connection structure used in a conventional space partition or window shade has the advantage of low installation cost.

Alternatively, the space separation structure 10 according to an embodiment of the present invention may be installed to be located outside the window 600 as in the conventional insect screen. This configuration has the advantage that the user does not have to be aware of the existence of the space separation structure 10 when opening and closing the window 600.

Alternatively, the space separating structure 10 according to an embodiment of the present invention may be installed to be opened and closed like a conventional sliding window through a dedicated rail installed in a window frame or on a wall near the window, or may use a hinge on a wall near the window. It can be opened and closed like a conventional casement window. This configuration has the advantage that the user can choose to use or not use the space separating structure 10 without the cumbersome detachment process.

On the other hand, the drawing shows that each unit is arranged to cross the overlapping portion (100A, 200A) as described above. The size of these overlapping portions 100A and 200A may also be selected according to the use environment and purpose. This is because as the units overlap each other, the more parts overlap, the longer the length of the passage to move to and from the space where the object or wave is separated (see Fig. 3). For example, if you want to increase aeration, you can have only a few overlaps. On the other hand, if the overlapping portions 100A and 200A are reduced, too much wind may be introduced in a windy environment, dust may be introduced together or rainwater blocking may be lowered, and the space separating structure 10 may be damaged by wind. Since the possibility of wearing can be increased, it is preferable to select the amount of overlap appropriately according to the needs and the use environment.

Similarly, the shape or structure of the overlapping portions 100A and 200A can also be selected. The embodiment of the figure is such that the size of the one side unit 100 and the other unit 200 and the size of the overlapping portion 100A of the one side unit 100 and the overlapping portion 200A of the other unit 200 are the same, thus each The proportion of overlapping portions in the unit shows the same structure. The size of each unit and the ratio of overlapping portions in each unit can be configured differently.

This configuration will be particularly useful when the overall shape of the spatial separation structure 10 is a curved surface rather than a plane. The description so far focuses on the use of the window 600 of FIG. 1 in its overall shape for ease of understanding, but the use of the spatial separation structure 10 according to one embodiment of the present invention is The present invention is not limited thereto and may be variously configured. As mentioned in the foregoing description of the convex shape of each unit, the overall structure of the spatial separation structure 10 according to an embodiment of the present invention also has various shapes consisting of one or more planes or curved surfaces or a combination thereof. It is also possible to have a detailed structure.

The direction in which each unit overlaps can also be selected to suit your needs. In particular, the direction of the passage of the object or the wave formed in the spatial separation structure 10 according to the embodiment of the present invention can be determined depending on which direction each unit overlaps.

For example, the embodiment of the figure shows a case where each unit is alternately arranged, but overlapping only in the horizontal direction, that is, the vertical direction of gravity. This embodiment is useful when installed or attached to a window or door in a longitudinal direction, ie in a direction parallel to gravity, to allow air to enter but to prevent the ingress of snow in the room. Since the indirect passage formed by the horizontally overlapping portions 100A and 200A is perpendicular to the direction of gravity, that is, the direction in which water falls or flows, water moving by gravity flows into the room through the indirect passage. It is not possible.

In this embodiment, each unit is opened in the horizontal direction so that the inlet passage inlet is formed, but is coupled through the unit coupling portion 300 in the vertical direction. This is a design consideration that is selected according to the purpose and the use environment as described above, but is not limited thereto.

The arrangement of the units in the horizontal and vertical directions can also be selected. For example, in the illustrated embodiment, one side unit 100 and the other side unit 200 are alternately arranged in the horizontal direction and alternately arranged in the vertical direction.

For example, in a portion where the unit shown on the left side of the third drawing of FIG. 4 does not overlap in the horizontal direction, one unit 100 which is the first unit at the top and the other unit 200 which is the first unit at the bottom are the unit coupling unit ( In the portions 100A and 200A, which are coupled through the unit 300 and overlapped with each other in the horizontal direction, the upper unit as well as the other unit 200 as the first unit at the top and the other unit 200 as the first unit at the bottom The second unit of the other unit 200 and the second unit of the lower side of the one unit 100 is also coupled in the unit coupling unit (300).

The shape of the unit coupling unit 300 may also be variously selected.

For example, in the example illustrated in FIGS. 2 and 4, the unit coupling part 300 shows a line shape. In this embodiment, the upper and lower connections of the indirect passages formed at the upper and lower ends of the unit coupling unit 300 meet each other and are completely blocked. Thus, for example, when the space separation structure 10 according to an embodiment of the present invention is used in the window, even if rainwater flows into the indirect passage at the top, it cannot go to the indirect passage at the bottom, and the principle described with reference to FIGS. According to the discharge to the outside space.

It should be noted that goodness is merely a simplified terminology for the convenience of understanding the concept. The unit coupling unit 300 is coupled to each unit in the form of a straight line or a curve or a combination thereof, the fastening method and shape may vary, and may have a variety of detailed structures. For example, the unit coupling part 300 may be coupled to each unit by integral molding, through a semi-permanent fastening element, or through a fastening structure detachably configured to each unit. The same applies to the other unit coupling unit 300 described later.

In another embodiment, the unit coupling part 300 has an open shape. That is, since each unit is not in contact with each other in the unit coupling portion 300 and are separated from each other, the indirect passages formed at the top and the bottom may be connected to each other. This has the advantage of smoothing the flow between the separated space of the object or wave, while also has the disadvantage that the blocking rate of the object or wave to be blocked can be lowered. For example, when used in a window, this configuration can increase the airflow rate, but rainwater may also be introduced somewhat.

However, this risk can be reduced by keeping the distance between the top and bottom. The unit coupling part 300 which combines the upper and lower ends separated from each other extends one side of the one side unit 100 and the other side of the other unit 200 in the horizontal direction, and thus the unit coupling part 300 formed to be horizontally long. The upper and lower connecting passages are separated from one side space or the other space by both interfaces of the two sides. Therefore, the rainwater does not flow through the unit coupling portion 300, rainwater flowing into the indirect passage at the top is also blocked from entering the room by both boundary surfaces of the unit coupling portion 300 and flows down the boundary surface or It is reflected to the other side and discharged to the outside through the indirect passage at the bottom.

Such a configuration may be viewed as a configuration in which each unit is superimposed not only in the horizontal direction but also in the vertical direction. It is open not only in the horizontal direction but also in the vertical direction, and unlike in the line-shaped embodiment described above with reference to FIG. 4, each unit is spaced apart from each other in the vertical direction as well as in the horizontal direction.

In another embodiment, the unit coupling part 300 has a barrier film shape. In this embodiment, it can be seen as a modification of the above-described linear unit coupling portion 300 or a deformation of the open unit coupling portion 300. Each unit is spaced apart from each other in the longitudinal direction as well as in the transverse direction as in the open type, but only in the transverse direction as in the linear and not in the longitudinal direction.

In addition, even in the case of a barrier film, the distance between the top and bottom can be. In this embodiment, it will be easily understood that the air flow rate will be a little lower than in the case of the open unit coupling part 300 having a distance between the upper and lower ends as described above, but will more effectively block the inflow of rainwater.

In the case of the closed type barrier film sealed at both the top and bottom, one side and the other end, as well as both sides, there is an advantage to provide an air layer. As described above, by placing the air layer, it is possible to block the heat exchange between the spaces. In summer, outdoor heat can be prevented from entering the room, and in winter, indoor heat can be prevented from flowing out. Since the unit coupling unit 300 is configured such that the air layer is formed, it means that a plurality of relatively large and thick air layers may be provided, and thus may be more effective in thermal cutoff. In addition, it is also possible to use a material that can further increase the thermal barrier effect to the unit coupling portion 300. In this case, materials different from the units 100 and 200 may be used from the beginning, or functional materials may be added.

Blocks are provided at the top and the bottom, but one or more of one end, the other end, and both sides are open, or one or more open holes may be provided in the form of an open barrier that is not completely sealed. This structure may be more suitable for dynamically adjusting the distance between the top and bottom, that is, the height of the unit coupling portion 300. In some embodiments, when the height of the unit coupling unit 300 is adjusted, the convexity of the units 100 and 200 may be adjusted. This means that the size of the air passages formed by the units 100 and 200 can be adjusted. Careful attention is paid not to increase the unit coupling part 300 to increase overall breathability.

The formation angle of the barrier film can also be adjusted. For example, when the rainwater, ultraviolet rays, etc. hit the blocking film, the blocking film (particularly, the blocking film located on the upper side, that is, the lower side of the unit 100, 200) may be formed to be inclined more than horizontally so as to be more effectively repelled to the outside space.

That is, the shape of the unit coupling unit 300 can be largely classified into a linear, open type, and a barrier film type, but the detailed structure can also be variously selected according to the needs and usage environments, and the specific fastening structure can also be variously selected. .

In addition, it will be readily understood that the shape of the unit coupling unit 300 can be classified by criteria such as whether the upper and lower ends are open, the distance between the edges of the unit to be coupled, and the distance between the upper and lower ends.

When classified into linear, open, and barrier type, it may be different depending on the detailed structure, but in general, it can be easily expected that the air permeability is open type> block type> linear, and the water blocking rate is linear> block type> open type. However, the prototype was produced in three forms (variable units such as unit size, overlap ratio, indirect passage diameter (convexity), material, etc.), and the test result of weatherproof blocking rate showed that open type also provides satisfactory blocking rate. Appeared to be.

On July 22, 2014, Seoul recorded 19.5mm, 23mm 55mm, 24mm 48mm, and 25mm 50mm, totaling 169.5mm of rainfall for 4 days. It was confirmed that no rainwater flowed into the indoor space separation structures 10.

Specifically, the test focuses on whether the user can install the space separating structure 10 according to one embodiment of the present invention in everyday life to be sure that the rainwater will not be damaged even if the window is opened during rainstorm. Proceed. First, a paper having a high absorption rate and visually easy to see when water is placed around the window in which the space separating structure 10 is installed is placed on the paper, the wall, the floor, and the objects around the window. There was no trace of splatter and it was softly touched. In addition, in order to check whether rainwater flows due to changes in time, location, and weather, a hand is placed close to each opening of the space separating structure 10 at a predetermined time, and no drop of rainwater is detected at any opening. . Since the blocking rate is 100%, the table or graph is omitted.

For the convenience of explanation and understanding, the specification has been described focusing on the embodiment of passing through the air and blocking the water by installing in a direction perpendicular to the window, using the term easy to explain, but the present invention This is not limited to this. For example, in the above description, terms such as top, bottom, and horizontal have been used assuming that the spatial separation structure 10 is installed in a direction perpendicular to gravity.

As an example to aid understanding, the spatial separation structure 10 according to one embodiment of the present invention may also be used as a shower curtain. When you take a shower, the view is blocked and water splashing is prevented, but the moisture is discharged immediately. If you manage it incorrectly, the bathroom, which is easily damaged by moisture, can be kept dry more easily and effectively. Especially if the bathroom with a window in a location where outsiders can glimpse can be more useful.

Space separation structure 10 according to an embodiment of the present invention is not limited to the space that can be separated. It can be used to separate not only indoor spaces but also outdoor spaces.It can also be used to re-separate already separated spaces such as cabinets, cabinets, drawers, wardrobes, refrigerators, boxes, and bags. have. For example, it may be useful for use in boxes for storing or transporting breathable goods such as fruits and vegetables. Particularly, when used for transport, the unit coupling part 300 may provide a shock absorbing function when the unit coupling part 300 is formed in a hermetic shielding film, so that the unit coupling part 300 does not have to be spent on a separate shock absorber.

It can also be used to protect fruits from impacts by placing them on one or more inner walls of fruit boxes, floors, walls or ceilings, which are used as shock absorbers or packaging materials. Conventional synthetic shock absorbers have poor breathability, so it is difficult to wrap all of the inner walls, and newspapers used instead have insufficient shock absorbing performance. In addition, the former has a problem in discharging moisture generated from the contents to the outside, the latter has a problem in preventing the intrusion of liquid from the outside, such as rain or snow. As a result, when you receive a fruit or vegetable delivery by courier, you will experience quite a bit of receding, broken or rotting experiences. Consumers, of course, do not like this experience, so suppliers are always at risk of losing customers. However, since the space separating structure 10 according to the embodiment of the present invention is excellent in both breathability, moisture control, and shock absorption performance, this risk can be significantly reduced.

It can also have the use of packaging materials to appeal to consumers beyond partitions and shock absorbers when used to separate and arrange fruits. A variety of designs can be easily implemented, and as attractive as a high-quality packaging can be realized, and the packaging value can be increased even when it is taken out of the box and displayed in a store, thereby increasing the value of the product at a low cost.

From the foregoing descriptions, it can be easily seen that the space separating structure 10 according to the embodiment of the present invention is not limited to the space separating purpose and use. It can also be used for applications that focus more on aesthetic and entertainment purposes than on practical ones. For example, it can be used for space sculptures, and can also be used for structures for advertising and promotion. Therefore, various structures, designs, and materials may be used for various purposes and purposes.

Now, a method of connecting the space separating structure 10 according to the present invention with another structure, a method of controlling the degree of space separating or the movement and exchange of interspace materials (or objects), waves, or both, and structures used therein An example will be described with reference to FIGS. 5 to 11.

5 conceptually illustrates a side view of the spatial separation structure 10 according to an embodiment of the present invention.

As described above, one or more one side unit 100 and the other side unit 200 of the space separation structure 10 according to the embodiment of the present invention are coupled by one or more unit coupling units 300, 1110 and the other side 1120, and the unit coupling part 300 may form a plurality of layers in a space between the one side 1110 and the other side 1120 by using an inclined barrier layer structure. have. For convenience of understanding, the structure of the barrier layer shape will be referred to as an interlayer separating surface 1130 in the following description. As one side 1110 and the other side 1120 is conceptually referred to as not one plane, as can be seen from the foregoing description, the interlayer separating surface 1130 is also a conceptual term and is shown in FIG. 5. The illustrated embodiment is only a simplification of the concept, the shape and structure may be very diverse (eg, the inclination angle of any of the plurality of interlayer separation surface 1130 or unit coupling portion 300 It may be the same or different from each other, the interlayer separation surface 1130 or unit coupling portion 300 may be a structure of a plurality of layers, etc.).

As described above, when the interlayer separation surface 1130 is inclined in a specific direction, there is an advantage in that it can better control the movement and exchange of space between the target material or the wave. Furthermore, in the embodiments described later in FIG. 6, the curling and unwinding may be more smooth and stable.

As shown, the spatial separation structure 10 according to an embodiment of the present invention may include a structure that is more stable and easier to connect with other structures. For example, the spatial separation structure 10 according to an embodiment of the present invention gathers one side 1110 and the other side 1120 of the spatial separation structure 10 in a triangular form (conceptual) as viewed from the side. The note may further include a first upper end 1140, and further include a second upper end 1150 for collecting one side 1110 and the other side 1120 of the triangle in the form of one side (conceptual). (The reason why the second top 1150 is illustrated as a curved surface in the direction surrounding the movable rod 7200 in the drawing will be described later with reference to FIG. 6). This configuration allows the top portion of the space separation structure 10 to be stably and smoothly connected to other structures (eg, hanging, hanging, attaching, the embodiment of FIG. 6, etc.), and the space separation structure 10 in use It will be easy to understand that it will keep you stable, but it should also be noted that the structure or method is not limited thereto. For example, the material of some or all of the tops 1140, 1150 may be the same or different from other parts of the spatial separation structure 10.

In addition, the bottom 1160 of the space separation structure 10 according to an embodiment of the present invention may not be connected to the interlayer separation surface 1130 as shown, and further, one side 1110 and the other side. 1120 or both may be elongated. This configuration allows the bottom portion of the space separation structure 10 to be connected to other structures stably, smoothly and flexibly. Two of the reasons are that the area of contact with other structures increases, and moreover, they can be used to make stable contact with other structures. As can be seen in the figure, the lower end 1160 may be freely used to fasten one side 1110, the other side 1120 and the interlayer separating surface 1130 with other structures. Thus, in one embodiment, as many or as few of these may be used for the fastening. On the contrary, even if the other part of the space separating structure 10 is fixed or fastened and the bottom 1160 is used without direct fastening with other structures, the space separating structure 10 can be stably maintained due to the structure of the bottom 1160. It will be easy to understand that there will be. In addition, the bottom 1160 may wrap another structure, and further, the user may easily adjust the degree of wrapping the structure. To this end, the lower end 1160 may further include a structure (eg, a heavy material or an object such as a weight) for receiving the help of gravity so that the lower end 1160 may be maintained as it is disposed. It may be the same or different from other parts of the separation structure 10. Although the structure and advantages of the lower end 1160 have been described above, it should be noted that the structure or method of the lower end 1160 is not limited thereto. For example, the lower end 1160 may be configured in a similar form to the upper ends 1140 and 1150 described above. Alternatively, the lower end 1160 may be configured to be fitted to another structure or the other structure is fitted to the lower end 1160.

6 illustrates an embodiment of a space separating structure driving unit according to an embodiment of the present invention.

The space separating structure 10 separates the space into one side and the other side and controls the exchange between the one side space and the other space. In some cases, it may be necessary to separate only a part of the whole space. For example, when the spatial separation structure 10 is used for a window to control the exchange of outdoor and indoor, sometimes the entire window may be covered to completely separate the outdoor and indoor, sometimes covering only part of the window. It would be more convenient.

The space separation structure 10 according to the present invention can be used in various ways as described above. For example, when used in a window, it may be installed in a window frame or a wall or ceiling 500 around the window, such as conventional curtains, blinds, roll screens and other shades, to have a shape and function similar to the window frame or window. It may be installed. Or it may be installed as a stand-alone independent structure, without direct coupling with the structure to be installed. Thus, the method and structure for adjusting the degree of space separation using the space separation structure 10 according to the present invention is very diverse. For example, it can be folded sideways like a conventional curtain, or it can be folded up like a blind or rolled up like a roll screen. Or, like a window, the whole can move sideways along the rail or rotate by a hinge. Even when used as an independent structure, various embodiments may be employed, such as a method of removing the whole sideways, a method of including a degree of space separation in the independent structure itself, and a method of receiving help from other means.

This specification describes one embodiment of a method and structure for opening up an upper space by rolling down the space separating structure 10, which may also be used to open the lower space. Opening the upper space instead of opening the lower space as in the conventional general method has a number of advantages. In particular, when using the space separating structure 10 to go out with the window open without worrying about the inflow of rainwater indoors, if you want the space separating structure 10 to separate only part of the window for reasons such as laundry drying, space separation It is better to place the structure 10 at the bottom of the window. In general, rainwater has a higher rate of entry into the bottom of the window (especially if the window is located close to structures that can reflect rain, such as the ground or a balcony). According to several years of experience of the inventor using the space separating structure 10 according to an embodiment of the present invention, the space separating structure 10 is placed only in the lower part of the window and the upper part of the window is open, unless a storm is predicted. I could go out without worry. There was no damage from the inflow of rainwater.

Another advantage is that it is effective to block chills in winter, and more light can be introduced that can be lacking in winter. This is a big advantage considering that it can greatly reduce the cost of heating by just blocking the cool air that enters the window and that depression can be caused by lack of light. Even in the summer, it is often effective to block the inflow of heat indoors (especially when the window is close to a structure that emits heat, such as the ground or a balcony) or, conversely, to the outdoor discharge of heat or the introduction of relatively cool air.

It will also be readily understood that blocking the bottom of the window rather than the top of the window will also be effective for privacy protection (ie, blocking the outflow of visible light outdoors). There are many other advantages as well, but for some of the reasons described above, it will be readily understood that the upper opening is generally better than the lower opening.

One of the reasons for using a conventional roll screen or the like to roll up may be because it is much easier than to roll down. The spatial separation structure 10 according to an embodiment of the present invention may also employ a structure to be rolled up as described above, of course, but to be rolled down is rainwater, heat, cold, or external gaze (ie It may be better to open the top, not the bottom, to more effectively achieve the object of the present invention to more effectively block unwanted alternating current, such as outdoor leakage of visible light. Therefore, it is necessary to invent a structure capable of rolling down the space separating structure 10 according to an embodiment of the present invention even with a simple structure.

6 shows one embodiment of such a structure. It is to be noted that this is a conceptual illustration and can be embodied in various forms and may be modified in other forms. This is true for all the drawings herein. In addition, in the description of the present specification, the space separating structure 10 may refer to the entire system including or using the driving unit 700 or the connecting unit 400, and also refers to only the shade itself that controls the exchange between spaces by separating the spaces. (The description of FIG. 6 is the latter, for convenience of explanation). Here, the term 'shade' is mainly described as the technique of the present specification is used as the space separation structure 10 for the window as described above, and will be described in correspondence with conventional shades such as curtains, blinds, roll screens, etc. It should be noted that the terminology selected for this purpose is merely a term for convenience of understanding and the spatial separation structure 10 is not limited thereto.

The space separating structure 10 according to an embodiment of the present invention may be rolled down from the by the drive unit 700, released from and returned to the top. The driving unit 700 is connected to the of the space separating structure 10, and the falling movement and the curling direction of the space separation structure 10 by the descending movement and curling movement and the unwinding direction of rotation and loosening movement and loosening movement It includes a moving rod 7200. In addition, the driving unit 700 is connected to the movable rod 7200 by the tension member 7500, and the movable rod 7200 is caused by its own downward direction rotation and upward direction rotation caused by the user pulling the tension member 7500. It includes a driving rod 7100 to cause the downward movement and rotation of the rotation and the upward movement and the rotation of the release direction.

Both ends of the driving rod 7100 are arranged side by side so that a relatively large radius (hereinafter, the large diameter portion 7120) and a relatively small radius (hereinafter, the small diameter portion 7130) are symmetric. The drawing shows an embodiment in which the radius of the center portion of the driving rod 7100 corresponding to the connecting portion of the space separating structure 10 of the moving rod 7200 is the same as that of the small diameter portion 7130, but is not limited thereto. In addition, the drawing shows an embodiment in which the large diameter portion 7120 is located outward in the order of the large diameter portion 7120, the small diameter portion 7130, the small diameter portion 7130, and the large diameter portion 7120, but is not limited thereto. .

At each of the large diameter portion 7120 and the small diameter portion 7130 at both ends of the driving rod 7100, there is one end of each tension member 7500, and the two tension members 7500 are separated but in the same direction as one. And rolled up in a manner. That is, in the drawing, when the tension member 7500 is seen from the left side from the start point of the large diameter portion 7120 on the left side (hereinafter all use the same viewpoint), it is wound in the clockwise direction to the user part A and the moving rod 7200, and then back again. After forming the ring which consists of B parts which go to the side, it winds again in the small diameter part 7130 clockwise, and goes to the end point of the small diameter part 7130. The right side is wound clockwise from the start point of the small diameter portion 7130 to form a ring consisting of the C portion and the moving rod 7200 coming out to the user side after going back to the back side, and then clockwise at the large diameter portion 7120 Wound to the end of the large diameter portion 7120.

That is, both ends of the driving rod 7100 are symmetrical to the large-diameter portion 7120 and the small-diameter portion 7130, but the direction in which the tension member 7500 is wound is not symmetrical but the two sides are the same. This structure greatly improves the convenience of the drive unit 700 according to an embodiment of the present invention. This will be described later, and when the tension member 7500 is first described, the tension member 7500 may be used for driving using tension and is not limited to a specific material and structure. For example, various types of thread, rope, cable, chain, belt, etc. may be used as the tension member 7500, and the details of the driving rod 7100, the moving rod 7200, or both depending on the selected tension member 7500. The structure may vary. The tension member 7500 preferably has a material and a structure having a large friction force with the driving rod 7100 and the moving rod 7200, and a detailed structure for this also brings the tension member 7500 in close contact with the tension and frictional force to transfer the driving force. It is desirable to be able to help.

In addition, although the drawing shows a structure in which the tension member 7500 is wound in one direction with both ends, it may be used by connecting both ends of the tension member 7500 to form a continuous loop. Such a structure may have advantages over the illustrated embodiment, but since the principle is the same, an embodiment of the present invention is shown in the form of winding from one end to the other as shown for convenience of description and understanding.

The figure shows an example of the above-described detailed structure for the moving rod 7200. The movable rod 7200 has an area in which both ends of the tension member 7500 are connected to the driving rod 7100 and the space separating structure 10 is connected to each other, so that the movable rod 7200 is connected to the driving rod 7100. It may be desirable not to. This may be solved by other methods, but a simple solution may be adopted to include a portion having a larger radius than other portions, such as the first guide 7220.

Furthermore, since the tension member 7500 may be in close contact with the movable rod 7200 to properly transmit the rotational motion by tension, some or all of the tension members 7500 may block the path that may be loosened beyond the movable rod 7200. It may further include a second guide 7230. As shown in the drawing, the first guide and the second guide do not greatly limit the moving member of the tension member 7500, and only maintain the simple structure because it prevents excessive derailment, and thus the entire moving rod 7200 and further the driving unit ( 700, the tension member 7500, and the connection part 400 may lightly maintain the weight of the entire object to be supported and driven. While the second guide is positioned at the bottom of the corresponding portion of the moving rod 7200, which is the remaining portion where the tension member 7500 can derail, the embodiment of the drawing uses a moving shaft 7210 so as not to disturb other structures. . Since the movable rod 7200 is supported by the tension member 7500 connected to the driving rod 7100, the shaft 7210 may not be necessary. However, the movable rod 7200 does not rotate even when the movable rod 7200 rotates. In order to prevent the second guide 7230 from interfering with the tension member 7500 even when the movable rod 7200 rotates. The illustrated second guide 7230 may be in the form of a cylinder, but more preferably in the form of a horizontal plane whose width does not exceed the radius of the first guide.

However, the first guide 7220 and the second guide 7230 are not necessarily required, and the second guide 7230 may be supported by the driving unit 700, the tension member 7500, and the connection unit 400. If the weight of the whole object exceeds the minimum threshold value, it may not need to be employed because it may be in close contact with the weight to obtain the required driving force. However, it is preferable that the weight to be supported and driven is light, and the second guide 7230 can be preferably employed because it helps to close the tension member 7500 even with a simple structure. In addition, since the moving shaft 7210 has a U-shape including the longitudinal direction, it is limited (for example, shaken) by using the connection portion 4210 or the hidden structure 7400, which describes the range of motion of the moving rod 7200. Up and down movement without rotation), the connection with the rail structure can be more smooth.

The figure simplifies the spatial separation structure 10, in fact the use of the drive 700 according to the invention is not limited to the spatial separation structure 10 according to the invention. For example, it can be used for curtains, roll screens and the like as well as other objects such as yarn.

Looking at the mutual motion of the drive rod 7100, the tension member 7500, the moving rod 7200 and the space separation structure 10, the drive unit 700 according to the present invention is the drive rod 7100 itself is also a tension member 7500 It is characterized by driving using a tension of). As can be seen in the figure, in order to rotate drive the drive rod 7100 using the tension of the tension member 7500, one (or two) of the rings, that is, A, B, C, and D, must be pulled down. It can be seen that. Since pulling up the tension member 7500 is not able to rotate the drive rod 7100, the description of pulling down may be omitted in the following description.

As described above, both ends of the driving rod 7100 have the large diameter portion 7120 and the small diameter portion 7130 symmetric with each other, but the direction in which the tension member 7500 is wound is not symmetrical but both sides are the same. Therefore, when the tension member 7500 is wound and loosened to the driving rod 7100, the same operation is caused, but from the user's point of view, there are two pairs A, D, B, and C on the front and rear sides. Since the operation when pulling down B and C can be easily understood by understanding the operation when pulling down A and D, only A and D will be described.

Pulling down tension member 7500 in part A, that is, when A is pulled down, drive rod 7100 rotates clockwise, so that parts B and C are rolled up and D is released Go down. Likewise, when the tension member 7500 of the D part is pulled down, that is, when the D is released downward, the driving rod 7100 rotates counterclockwise, so that the B and C parts are wound up and A is lowered. Freed down. That is, A and D have opposite directions of rotation of the driving rod 7100, but the same direction of movement of the tension member 7500 is the same.

A, D, B, and C have a common point of being connected to the large diameter portion 7120 and the small diameter portion 7130, respectively. Since the large diameter portion 7120 and the small diameter portion 7130 are different from each other in the extent that the tension member 7500 is wound or unwound by a radius difference, when A or D connected to one of the large diameter portions 7120 is pulled down, that is, When the tension member 7500 wound around the two large diameter portions 7120 is released, the tension members 7500 are wound around the two small diameter portions 7130, and at the same time, the rings, that is, the A, B, C, and D portions are all lengthened. Therefore, the moving rod 7200 is lowered. The reason why the A, B, C, and D parts are long will be understood that when the driving rod 7100 is rotated once, the small diameter portion 7130 may not be wound around the large diameter portion 7120.

The rotation direction of the moving rod 7200 is reversed. Pulling A moves the rod 7200 in the same clockwise direction as the driving rod 7100, and pulling B moves the movable rod 7200 counterclockwise. Therefore, the space separating structure 10 is connected to the moving rod 7200 as the first top 1140 as shown in the drawing is wound when the moving rod 7200 rotates in the clockwise direction and is loosened when rotated in the counterclockwise direction. If you pull, you will descend and unwind, but if you pull D, you will descend and unwind. Since it is A on the user side, the user will naturally use A.

At this time, if the bottom 1160 of the space separation structure 10 is fixed to the lower part of the space to be installed as in the conventional home, it can be rolled down using A to open the upper space, but the space of the space to be installed In the case of fixing the upper portion, the size of the opened lower space can be reduced while releasing the space separating structure 10 rolled up using D. This is an effect of opening the bottom of the window while drying from the bottom similar to the conventional blinds. That is, the driving unit 700 according to the present invention can easily implement the opposite effect by only slightly modifying the configuration or method of use, the structure of the driving unit 700 is much simpler than the conventional blind, roll screen, etc. It offers the advantage that two opening directions can be selected and used according to needs that roll screens and the like have not provided. That is, in this specification, for convenience of description, it is assumed that an operation of sending an object such as a space separating structure 10 or other shades in a downward direction is described, but the present invention is not limited thereto, and the user may easily change to the opposite direction. Can be used

In addition, it is easy to install after determining the direction in which the space separating structure 10 is dried. Conventional roll screens have a chain or thread on one side (usually on the right side), so you can change the chain or thread even if you want to change the direction in which you dry (for example, by rotating the product to To a safety issue (e.g. when installing on the right side of a large window, if there is a wall to secure on the right side, but the window is a moving part on the left side, and the chain or thread gets caught in the window). There was a limit. However, the driving unit 700 according to the present invention is free to use after rotation because the left and the right has the same structure.

Moreover, since the position of the tension member 7500 according to the moving direction of the driving unit 700 according to the present invention is divided, which side of the thread should be pulled up and which side should be pulled down like conventional blinds? There is no inconvenience to go through trial and error every time. For example, the user of the embodiment of FIG. 6 easily learns that when the user side tension member A on the left side is pulled down, the spatial separation structure 10 moves down, and the user side learns that the user side tension member C rises up when pulling the user side tension member C on the left side. I can remember it. That is, the driver 700 according to the present invention provides an improved user interface (UI) than the conventional shades.

Furthermore, by further using the structure described below with reference to the drawings, the drive unit 700 according to the present invention allows the use of the space separation structure 10 or other shades more safely and conveniently.

In addition, conventional blinds or roll screens have a shade part integrated with the housing containing the drive structure, the housing is fixed to the upper part of the window, and the drive structure is complicated, making it difficult and cumbersome to replace only the shade part or if some parts are broken. The driving unit 700 according to the present invention may easily separate the space separating structure 10 (or other applications), and may easily lower the portion to which the space separating structure 10 is connected to the bottom of the window, and the driving unit 700. Due to its very simple structure, there is little risk of breakdown and it is easy to replace even if it breaks down. Therefore, using the drive unit 700 according to the present invention can be frequently replaced with a shade suitable for the weather or mood change according to the season, it is very economical because it can be done by itself because it does not need any special expertise or technology, complicated parts.

The reason why the driving unit 700 according to the present invention can provide such a dramatically simple structure is that it is not necessary to further provide a structure for maintaining the current state of the shade. Conventional blinds or roll screens pull the thread or chain to raise the shade, and then release the thread or chain to release the tension, so the shade goes down again by gravity, so there is an additional locking structure to hold the shade in place. More needed. Therefore, in general, the lock structure prevents the movement of the gear, so the user has to perform conscious actions such as lifting and releasing the thread or chain at a slightly larger angle to unlock the lock structure and change the vertical position of the blind or roll screen. have. This not only complicates the drive structure but also causes inconvenience in use and increases the risk of failure. For example, the lock structure is released when the thread or chain is lifted 30 degrees in a specific direction, but if the user lifts only 15 and releases it or lifts it in the other direction, the lock is not released. If you lift and release it, you will be subject to torsional torque each time, which may lead to misalignment of the drive or shortened component life. Moreover, because the behavior of unlocking varies from product to product, the risk of user inconvenience and failure increases further.

However, the drive unit 700 according to the present invention does not require such a locking structure at all, and the user only needs to select one of the left and right tension member 7500 portions (A or C) and pull it down. There is no component that is susceptible to torsional torque, and it is also possible to guide the puller in another direction by using a structure described later. The reason why the driving unit 700 according to the present invention does not need a separate locking device is because the radius difference between the large diameter portion 7120 and the small diameter portion 7130 plays a role. The fact that such a configuration can keep the load in the raised position has already been demonstrated in the hoisting machine used in China, the Chinese windlass, and thus the detailed description is omitted.

The driving unit 700 according to the present invention uses this principle, but the crank handle is removed, the tension of the tension member 7500 connected to one end of the driving rod 7100 rotates the driving rod 7100 and accordingly the driving rod ( The tension member 7500 connected to the other end of the 7100 is wound or released, and the tension is also used to drive the driving rod 7100 itself. In addition, by moving the rod 7200 to the hooks on both ends of the driving rod 7100, the tension member 7500 can be rotated, as well as lift or lower the load, that is, the movable rod 7200. In addition, the movement and rotation of the movable rod 7200 not only moves the object, such as the spatial separation structure 10 or other shades, but also facilitates winding and unwinding. In addition, the simple structure of the interaction between the driving rod 7100, the movable rod 7200, and the tension member 7500 enables the object of the space separating structure 10 or the other shades to maintain the current state without an additional locking device.

In addition, since the length of the tension member 7500 wound by the both ends of the drive rod 7100 is constant, the minimum value and the maximum value of the ring parts A, B, C, and D are fixed. This may be determined in consideration of the vertical length of the space separating structure 10 and the vertical length of the space desired to be opened and separated in a space (eg, a window or a door) using the space separating structure 10. That is, the driving part 700 and the space separating structure 10 according to the present invention also have an advantage that a certain part is always open and a certain part may always be separated at a place where it is installed. For example, the user may want to leave about a quarter of the bottom of the window always separating the indoor and outdoor spaces when the space separation structure 10 is fully lowered. This way, if a certain portion of the lower part of the window is always separated, the space separating structure 10 can be lowered or raised in consideration of other needs without considering the minimum height to prevent the user from preventing the inflow of rain indoors. As we can raise, it is convenient. Similarly, the user may wish to leave about one tenth of the upper portion of the window open at all times without separating the indoor and outdoor spaces when the space separating structure 10 is fully raised. Therefore, when the loop part is shortest, when the moving rod 7200 is at the highest position, that is, when the space is separated by the space separating structure 10 is the largest, and when the ring part is long, the moving rod 7200 is the most. When the position is low, that is, when the space is opened by the space separation structure 10 is the largest, considering the minimum and maximum value of the length of the ring portion (A, B, C, D) .

7 to 8 illustrate examples of structures and methods that can further improve the safety and convenience of the driving unit 700 according to the present invention. 7 and 8 illustrate embodiments of the space separating structure concealment means according to an embodiment of the present invention.

According to the news, a significant number of infants die every year worldwide due to accidents involving blinds or roll-screen strings, and regulations have been made to ensure that blind strings are automatically cut when a load exceeds the threshold. In the United States, this threshold is 4 kg, but nevertheless infant and toddler accidents occur. In Korea, the threshold is 10 kg, but many producers do not comply. Even if the rule is followed, this is a costly but ineffective solution. A less expensive solution is to fasten the blind cord to the clip and secure it to the wall. Not only is it uncomfortable because you have to buy it separately and use it again after removing it from the clip, and you can cause a safety accident due to carelessness. And even if you pay attention, you can't completely control the behavior of infants and toddlers. Even without infants, the inconvenience and safety problems as described above in FIG. 6 always exist. Moreover, elongated threads tend to twist or wind up other objects.

Therefore, the driving unit 700 according to the present invention divides the position of the tension member 7500 ring to be used in accordance with the operation to the left and right to enhance the convenience, and conveniently hides the parts that are not necessary for the operation among the rings as much as possible. The safety can be further improved. By exposing only the rings A and C on the user's side, the user can be prevented from accidentally pulling B and D on the back, preventing A and B, C and D from twisting each other, and above all Can be prevented. Safety is increased even when using a conventional, expensive solution or without the user paying attention. In addition, as shown in Figure 7 configured to expose only the minimum portion of the driving ring A and C is further improved safety.

7 is an embodiment in which the exposure ranges of the drive rings A and C are determined. As described in FIG. 6, the minimum and maximum values of the lengths of the ring portions A, B, C, and D may be determined in consideration of the degree to which the space is opened or separated by the space separating structure 10. In addition, the position of the driving rod 7100 may also affect the minimum value and the maximum value. For example, in some installations it may be necessary to install the drive rod 7100 far away from the window, in which case it would be better to add that distance to the minimum and maximum values.

Fig. 7 exposes only the minimum value portion of the drive ring portions A, C length so defined. The non-drive rings B and D are entirely hidden in the hidden housings 7400 and 400, and the drive rings A and C are also hidden in the hidden housings 7400 and 400. Since the hidden housings 7400 and 400 are hollow, the loop portions A, B, C, and D hidden in the hidden housings 7400 and 400 as the user pulls the driving rings A and C of the exposed portion. ) Is freely adjusted in length, and the connected moving rod 7200 is also unobstructed in operation (because both ends of the moving rod 7200, that is, the portion in which the loop is wound, move and rotate inside the hidden housings 7400 and 400, An opening for this is also required in the housings 7400 and 400. The openings may also serve as guide rails for smoothly moving and rotating the moving rod 7200 as described above. It is not intended to explain how to hide the (). Therefore, even if only a specific portion of the drive ring (A, C) is exposed, the drive unit 700 and the space separation structure 10 according to the present invention operates smoothly.

The figure shows only the hidden housings 7400, 400 and shows the ring portions A, B, C, D being exposed out of the two openings 7410, 7420 of the top surface, for illustrative purposes. The hidden housings 7400 and 400 may be a part of the connection part 400 to be described later, and may be connected to another hidden housing (not shown) at the top to hide a corresponding portion (or all) of the driving rod 7100. . That is, the hidden housings 7400 and 400 may constitute a part of the connection part 400.

The hidden housings 7400 and 400 according to the present invention are not limited to the driving part 700 according to the present invention or the space separating structure 10 according to the present invention. That is, the hidden housings 7400, 400 can also be used to expose only a portion of a thread or chain of shade, such as conventional blinds, roll screens. In particular, conventional shades generally use loops of thread or chain, so the minimum and maximum values of the loops are the same. That is, the length of the loop does not change. This makes it easier for users to select the exposure range. Further convenience is made possible by allowing the user to dynamically set the exposure range as needed.

8 is an embodiment in which the exposure range of the drive rings A, C changes dynamically. The hidden housings 7400, 400 of FIG. 7 may be part of the connection 400, while the concealment structure of FIG. 8 may be inserted and partially hidden within the connection 400.

The driving rod 7300 is connected to the driving rod 7100 and the shaft 7310, and the position is fixed as the driving rod 7100. The hidden rod 7300 is driven and rotated by the driving rod 7100 like the movable rod 7200, but is directly driven by friction with the driving rod 7100 rather than the tension of the tension member 7500. Therefore, unlike the movable rod 7200, the hidden rod 7300 is in the opposite direction of rotation to the driving rod 7100.

The hidden film 7320 is wound or unwound by the rotation of the hidden rod 7300. Referring to the drawings, when the driving rod 7100 rotates in the direction of moving down the moving rod 7200, that is, when the ring portions A, B, C, and D are long, the hidden film 7320 is also unwinded and lengthened. When the driving rod 7100 rotates in the direction of lifting the movable rod 7200, that is, when the ring portions A, B, C, and D are shortened, the hidden film 7320 is also wound up and shortened.

Each hidden film 7320 separates each of the drive ring portions A and C from the non-driven ring portions B and D, and hides B and D from the user. Although the drawings show B and D for the sake of understanding, in practice, since the movable rod 7200 is present under the hidden film 7320, even though B and D are invisible or partially visible, it is difficult for a user to pull out by mistake. In addition, as described above, since the hidden rod 7300 and the hidden film 7320 are partially hidden by being inserted into the connection part 400, B and D are more concealed.

8 is a simplified diagram to illustrate the concept, and various detailed structures may be used or modified. For example, a structure, a material, or both may be employed to facilitate the drive between the drive rod 7100 and the hidden rod 7300. In addition, the housing 400 for inserting and supporting the hidden film 7320 is a guide rail that prevents shaking while the side surface of the hidden film moves along a specific path in order to prevent wobble when the length of the hidden film 7320 is increased. Or it may further comprise an opening. This is because the structure similar to the guide (for example, the structure formed in the longitudinal direction of the rail, groove, jaw or the like or the opening formed in the longitudinal direction) to prevent the shake of the movable rod 7200 will be omitted. A similar concept is the guide rail or opening for the space separation structure 10 which will be described later with reference to FIG. 9.

Figure 9 illustrates one embodiment of a spatial separation structure connecting portion according to an embodiment of the present invention. It is a conceptual front view, and the conceptual structure can be modified in various ways. For example, the lower connecting portion 430 is positioned below the side connecting portion 420 without overlapping the vertical position with the side connecting portion 420, but is not limited thereto. In addition, although the central portion of the driving rod 7100 is shown, the driving rod 7100 may be completely hidden. Each part of the connection part 400 may be manufactured to be detachably attached to each other in part or all as a separate module, or may be permanently fastened or integrally molded. Each part of the connector 400 may or may not be used as well. For example, the drawing shows an embodiment in which the upper end of the side connecting portion 420 serves to fix the shaft of the driving rod 7100 without the upper connecting portion 410, but is not limited thereto.

On the contrary, the lower connection part 430 may not be used. The bottom connection part 430 may perform one or more of fixing and supporting the bottom of the space separation structure 10, interaction with the side connection part 420, preventing indoor inflow of rainwater, outdoor discharge of rainwater, or the like. However, in an embodiment that does not require such a function, the lower connection part 430 may be omitted.

Similarly, the side connections 420 in the figure may include, but are not required to include, a first housing area 4210 to conceal a portion of the drive portion using the tension member 7500 as described above. However, it may be desirable to include the first housing area 4210 to provide the ability to conceal a portion of the tension member 7500 for various advantages as described above. The first housing area 4210 conceals a portion of the tension member 7500 and both ends of the movable rod 7200, and can further conceal both ends of the driving rod 7100. In addition, a means for fixing the shaft 7110 of the driving rod 7100 may be further provided. In addition, as described above, it is possible to provide a longitudinally long guide (eg, a structure of a rail, a groove, a jaw, etc.) which can be used more smoothly and stably by limiting the degree of freedom of movement of the movable rod 7200, The opening itself for inserting the end of the moving rod 7200 may be configured to play such a role. In addition, as described above, when there is a long portion formed in the longitudinal direction on the shaft (7210) of the movable rod 7200, inserting the portion into the guide of the first housing area 4210 to better perform the role of the guide. Can be. To this end (or even when the shaft 7210 of the movable rod 7200 is not used or formed longitudinally long), the first housing area 4210 may also form a guide on a surface corresponding to the insertion opening of the movable rod 7200. It is also possible for the guide to take the form of an opening. The descriptions also apply to the above-described hidden film 7320 and the second housing region 4220, which will be described later. In the case of the hidden film 7320 and the space separation structure 10, the side surfaces thereof are vertically long. The edge can be inserted into the guide.

In addition, the lateral connection 420 of the figure includes a second housing area 4220 into which both ends of the object are inserted, for connection (installation), drive, or both, to the spatial separation structure 10, a shade or other structure. However, this is not required. However, the second housing area 4220 has an advantage that both ends of the object 10 do not leave a certain range. For example, conventional shades such as curtains, blinds or roll screens have a disadvantage that the side and the bottom flutter away from the window because only the top is fixed when the wind blows. This can distract the user due to fluttering noises and constantly moving shades, and increases the failure rate by continuously impacting the blinds themselves and the windows, as well as making conventional shades more difficult to prevent rain from entering the room. It may be the reason. On the other hand, the space separating structure 10 according to the present invention is fixed to the structure in which the lower end 1160 is not moved, and is not only fixed to the movable rod 7200, but also the side is fixed to the second housing region 4220. Can be. Therefore, the above problem does not occur. In addition, since the air passes through the ventilation passage of the space separating structure 10 itself according to the present invention, even if the wind is blown or the object is fixed to all the edges, such as tearing or desorption by the pressure of the air caused by the wind It does not occur in the space separation structure 10 according to the invention. In addition, unlike conventional curtains or roll screens, even if all the edges are fixed, the wind enters the room by aeration, so even on a windy day, open the window and enjoy the cool breeze or the laundry without worrying about the above-mentioned problems. It may be better to dry the back.

In addition, this configuration has the advantage that one end of the object 10 is moved and rotated along the preferred path, so that it is more smoothly wound or rolled and unwound and maintains the state. To this end, it is possible to further provide a guide formed in the longitudinal direction as described above. Since the first housing area 4210 has been described, a detailed description thereof will be omitted.

The second housing area 4220 also prevents the side of the space separation structure 10 according to the present invention from becoming a gap into the interior of unwanted material (eg rainwater, dust). This is omitted because it is easily understood, but the side connection portion 420 may further include a structure for discharging rainwater that may flow into the housings 4210 and 4220 by wind or the like. As shown, the lower ends of the first housing region 4210 and the second housing region 4220 are configured to be inclined (4212, 4222), and rainwater collected by gravity is discharged through the drain hole 4224. In addition to the view from the front as shown in FIG. 9, the slopes 4212 and 4222 can be formed even when viewed from the side as shown in FIG. 10. It will be readily understood that (4224) may not take up much space. The direction of the inclination is directed toward the outdoor side of the window, it may be desirable to place the drainage 4224 as close to the outdoor side as possible, but is not limited thereto. The drawing also shows an embodiment in which the inclinations 4212 and 4222 of the first housing region 4210 and the second housing region 4220 are configured differently, but are not limited thereto.

10 and 11 illustrate embodiments as viewed from the side of a space separating structure connection unit according to an embodiment of the present invention. Although the drawings are conceptual views of the side connecting portion 420, the upper connecting portion 410, the lower connecting portion 430, or both are omitted, but the illustrated connecting portion 400 may include or be connected thereto. At this time, these positions can be configured in various ways. In fact, although FIG. 11 is illustrated as being a side connection 420, this is only for convenience of understanding because it is viewed from the side, and the illustrated connection part 400 may not include the side connection part 420.

10 is a view for explaining the attachment of the connecting portion 400 including the side connecting portion 420 to the installation space. You can use the upper and lower window frames or the walls or ceilings or floors above and below the window frames. Since the present specification does not distinguish the window frame, the wall, and the ceiling, the drawing shows that the wall above and below the window frame can be used as the first attachment portion 4230. In the drawing, the second attachment portion 4240 is illustrated in a U-shape to illustrate that this portion may not be attached thereto, but is not limited thereto. In other words, this part can also be used for attachment. For example, when attaching to the left and right walls of the window frame, some or all of the entire attachment surface may be used for attachment without distinguishing the first attachment site 4230 and the second attachment site 4240. When the side connecting portion 420 is used to install the space separating structure 10 in a large window, some side connecting portions 420 may not use the second attachment portion 4240 for attaching. In this case, the second attachment portion 4240 may maintain a single shape or adopt a U shape as shown in the drawing. In addition, a material such as a buffer or an elastic body may be used for the second attachment portion 4240. This will allow you to open and close the window freely, preventing rainwater from entering, and even preventing the window from rattling.

That is, the connection part 400 according to an embodiment of the present invention can reduce the window shake in the wind, as opposed to the impact of hitting the window while the conventional blind or roll screen flutters in the wind. In addition, the use of a material suitable for blocking the cold, wind or both in addition to providing a cushioning function to the second attachment portion 4240, it is possible to further provide an effect of reducing the heating cost in winter.

11 is not limited to the position when viewed from the side of the connector 400, and further describes that it can be moved dynamically as needed.

In the illustrated embodiment, the top connection 410 provides a sliding support member 4110 (e.g. a rail) such that the spatial separation structure 10 is placed in the window frame or installed directly in front of the window frame as a conventional conventional shade, or not at all. Explain that you can move away from the window. Positioning in the window frame would have the advantage of better preventing the entry of unwanted materials or waves, such as rain or dust, into the room. Positioning away from the window may be useful when the spatial separation structure 10 is desired to be removed for cleaning or the like. Alternatively, indoor and outdoor emissions of unwanted visible light can be limited to moderate levels (eg strong sunlight, strong outdoor lighting, privacy exposures), and indoor and outdoor exchange of air can be useful. The embodiment of the figure provides a positioning function according to this need by including a sliding function in the connecting portion 400 according to the present invention.

As such, the connection part 400 according to the present invention may provide a function capable of dynamically adjusting the degree of space exchange between the space separating structures 10 according to the present invention, similarly to the driving part 700 according to the present invention. . Furthermore, like the driving unit 700 according to the present invention, the connection part 400 according to the present invention may dynamically adjust the degree of exchange between spaces even when used in a conventional shade or other object, not the space separating structure 10. It can provide a function.

When using the space separation structure 10 according to an embodiment of the present invention, the number is not limited as described above, it is also possible to use several types of embodiments together when a large number of individuals. For example, by installing different types of space separation structures 10 at the bottom and top of the window, the space separation structure 10 at the bottom is fixed and the space separation structure 10 at the top is a walk or folding or the like. (Of course, the space separating structure 10 at the bottom can also be detachable and can be deformed as necessary). In addition, some embodiments 10 may be positioned within the window frame, and some embodiments 10 may be configured to be located outside the window frame. It is also possible to combine, modify, or both of these example configurations. By using a plurality of space separation structure 10 in this way it is possible to increase the degree of control over the exchange of space, such as light transmission or ventilation. It is particularly advantageous to reduce unwanted flow. For example, summer night pests such as mosquitoes and moths can be better prevented from entering the room. Not only does the light not leak directly, but even if pests react to the light, it becomes difficult to enter the room. This effect can be obtained even by using only one space separation structure 10 according to an embodiment of the present invention, but a larger effect can be achieved by using a plurality of space separation structures.

Conventional techniques such as curtains and blinds are swept away on a windy day, so it is difficult to leave a window open on a windy day. It's crazy and flutters, but it's fragile because it's constantly going on. In particular, the fixing means may fall off if it cannot stand. In addition, the prior art is not fluttered in the wind to prevent the inflow of rain, it is difficult to open the window on a rainy day when the wind is blowing. This is particularly inconvenient during summer. The outside is cool due to the wind, but the interior is often hotter, humid, and stuffier. However, the spatial separation structure 10 according to the embodiment of the present invention blows much less than the prior art even on a windy day. Unlike the prior art, not only is the surface area subjected to the wind force, but also because the passage through which the wind is well formed. Therefore, the spatial separation structure 10 according to an embodiment of the present invention is less burdened than the conventional fixing means, the cost is reduced, it can be easily used even in the difficult installation in the prior art. More importantly, the space separating structure 10 according to the embodiment of the present invention not only prevents the inflow of rain even on a windy day, but also provides a passage for the wind, so that the summer can be kept cool. It also provides a passage for the wind and reduces the intensity of the wind, thus preventing excessive wind and contaminants. Therefore, the user of the space separation structure 10 according to an embodiment of the present invention, unlike the prior art users, can enjoy the benefits of rain and wind to cool the heat.

Furthermore, according to the embodiment, the user of the space separation structure 10 according to the embodiment of the present invention can also lessen the worry about thieves or sex offenders who invade through windows or doors opened in summer. For example, the spatial separation structure 10 according to an embodiment of the present invention can be implemented to be able to be opened and closed and locked like a conventional window, and when the user locks the space separation structure 10 when going out or going to bed. Therefore, it will be easy to understand that not only the eyes of outsiders but also their intrusions need not be worried about. In such an embodiment, it will be easily understood that it is preferable to use a more rigid material, and the fact that it can be opened and closed and locked like a conventional window is merely for convenience of understanding and can prevent outsiders from invading. It will be readily understood that the structure of the embodiment is not limited thereto.

For example, the spatial separation structure 10 may be implemented not normally open or closed or without the ability to open and close. For convenience of understanding, for example, the space separating structure 10, unlike the conventional method grate or screen (note that this is also an example), not only prevents the intrusion of the outsider but also prevents the outsider's eyes. Unlike the prior art, the breathability and ventilation is good, so that the user can be more comfortable.

In addition, the spatial separation structure 10 according to an embodiment of the present invention may further include an intrusion detection means, unlike the prior art in which the position of the intrusion detection means is exposed or an additional means for hiding it is needed. Means are naturally hidden. It is furthermore advantageous to distribute the intrusion detection means throughout.

In addition, even when implemented as a conventional window, the implementation options vary widely, and are not limited to the structures exemplified herein. For example, even if the spatial separation structure 10 is implemented as a conventional sliding window, it can be implemented to be opened and closed by moving sideways in addition to the conventional window (or triple if it is a double window), and the conventional window It may be implemented to replace some of them (keep double if it is a double window. For example, remove the inner window and use the structure 10), or it may be implemented to replace some of the conventional window structure (double if it was a double window). Maintain the window frame, for example, interchange the screen part, replace the window part of the window, etc.).

Thanks to this flexibility of the space separation structure 10, the user can enjoy a crime prevention effect even without separately installing a structure such as a grate to prevent outsider intrusion. Therefore, it is not necessary to make a hole in the building for fixing the crime prevention structure, not only beautiful but not expensive, difficult to maintain, and can be safely and comfortably at low cost without an inconvenient structure. In particular, unlike the prior art, there is no burden of detachment, it is convenient because the use of the window does not interfere even when it is necessary to enter through the window, such as moving or fire.

In addition, this flexibility of the spatial separation structure 10 indicates that it can be useful in the winter as well as summer. Improper winter ventilation can lead to many health and maintenance problems. Nevertheless, people tend not to ventilate well in winter. It's because they don't like cold or cold winds, but because it requires heating to warm up the indoor air, which is coldened by ventilation, ventilation can cause more energy consumption. Therefore, there is a need for a method to reduce the inflow of cold and cold air during ventilation.

The space separating structure 10 according to an embodiment of the present invention is useful because it prevents cold wind and cold from directly flowing during ventilation. In particular, the space separation structure 10 has the advantage that the implementation can be selected very flexibly as described above, if it is configured in multiple layers, it will be readily understood that it will be able to better block the inflow of cold during aeration. That is, the present specification has been described as only one side and the other side for the convenience of understanding, but this is only for convenience of explanation, the passage of the object (for example, air, etc.) may be a connection of openings formed in a plurality of surfaces. Be careful. In addition, this may be implemented by overlapping a plurality of spatial separation structures 10, thus providing greater convenience and wider utility to the user.

It is again emphasized that the arrangement of the openings is also not limited to the drawings and description herein. For example, in some longitudinal positions, the openings may be located only on one side, and in another longitudinal position, the openings may be located only on the other side. In addition, the openings may not be planar and may be formed together or curved on a plurality of surfaces. For example, when one side, the other side, or both (or additional faces when implemented as multiple facets as described above) are configured to fold like a fan, openings may be formed in the fan or fan bone section. It will be easy to understand. Implementing components (eg, one side, the other, etc.) with irregularities like debts (eg, fan, fan, etc.) allows the spaces surrounding them to contain more air, thus preventing cold. It will be understood.

In addition, as described above, since the spatial separation structure () according to the embodiment of the present invention may be used for scattering of light, not only does it impede the inflow of sunlight in winter than conventional technologies such as curtains, but rather It can help the influx of light. In winter, not only are there many health problems caused by not being able to get enough sunlight, but it is also easy to experience the need to use artificial lighting during the day. The use of another spatial separation structure 10 in one embodiment of the present invention can alleviate this problem because light is repeatedly reflected to components (eg, one side, the other side, etc.). In addition, as described above, the implementation can be very flexibly selected, and materials or substructures that help reflect light can keep the interior brighter, and sunlight can also reduce heat, thereby reducing heating costs. Furthermore, depending on the setting, it is possible to implement the light in such a way that the light is better introduced or the light is blocked more. This flexibility allows the use of a single spatial separation structure 10 regardless of the season, unlike conventional techniques such as curtains that must be made separately for summer and winter. Alternatively, since various combinations of the plurality of spatial separation structures 10 are possible, there is also a convenience that the user can select the optimal combination according to the season or need.

In addition, since the spatial separation structure 10 according to the present invention is not limited to the implementation method selection as described above, not only several overlapping implementations as in the above-described example, but also an implementation of connecting up and down can be selected. In addition, such a connection can be implemented in a variety of implementations, such as a removable connection, a semi-permanent attachment, the objects to be connected do not have to be the same implementation. For example, if an embodiment using a more waterproof and rigid material or structure is used at the bottom of the window, and an embodiment using a more flexible material or structure at the top of the window and more flexible to inflow or blocking light, It will be easy to understand that it can be increased.

As mentioned above, the description herein focuses primarily on windows and doors, but it is again emphasized that this is for convenience only. For example, there is an advantage over the prior art even when used as a sunshade structure. For example, the conventional awning has a problem of falling down due to the weight of the rain when a lot of rain, the spatial separation structure 10 according to an embodiment of the present invention does not have such a problem because the rain is not accumulated. In addition, as described above, the wind is not only cool because it passes, but also less flutter in the wind, the risk of damage to the wind is significantly reduced.

In particular, the space separating structure 10 according to an embodiment of the present invention not only has the above-mentioned advantages when used as an air conditioner outdoor unit roof or a protection facility, but also prevents hot sunlight from heating the outdoor unit. The advantage is that it allows for better release than before. In addition, the general causes of dirt such as dust and fallen leaves not only pollute the outdoor unit, but also make pigeons reluctant to sit in the air conditioner outdoor unit. Since pigeons generally like to sit on air conditioners outdoor units, it is easy to soil the outdoor unit by feces or the like, which adversely affects the user's health and gives off odors, thus preventing pigeons.

12 conceptually illustrates a spatial separation structure and connections according to one embodiment of the invention.

FIG. 12 is a conceptual view of a conventional curtain or blind when blowing in the wind. As can be seen from the drawings and the experience, the prior art does not cover the lower and side portions of the window properly, there is a problem such as rain or wind, cold, peeping eyes of the person who wants to block properly the object.

On the contrary, the second drawing shows that the space separating structure 10 according to the embodiment of the present invention not only blocks the circumferential surface of the lower part of the window, the side of the window, etc., but also the space separating structure 10 can retain air. Conceptually, it can provide one or more of the additional benefits of creating a space (H), window lock, and light control.

The windows and curtains are very familiar to people and will be readily understood by those skilled in the art, and for convenience of illustration and description, side views have been omitted, and illustrations of other elements, such as bottom 10B, have been briefly conceptually illustrated. This is to emphasize that the details of implementation may vary. For example, although the figure shows that a portion of the bottom surface 10B and the side surfaces (not shown) and the front surface 10F may be spaced apart from the window 600, the top surface (not shown) may also be spaced apart from the above description. Thus, it will be readily understood that the technique for other circumferential surfaces can be applied. That is, the spatial separation structure 10 according to one embodiment of the present invention, unlike the prior art, one or more of the bottom surface, side surface, top surface (for example, the lower portion of the side surface (not shown), etc.) or the entire surface (for example, the side surface (not shown) By further including the entire city), it provides various advantages. In addition, the front face 10F may be further added according to an embodiment or a user's selection. Therefore, for convenience of description, one or more of the bottom surface 10B, the side surface (not shown), the top surface (not shown), and the added front surface (not shown) are collectively referred to as the circumferential surface 10B (the circumferential surface for convenience). Note that part of (10B) (such as the bottom portion of the side (not shown), etc.) is also referred to as circumferential surface (10B). Also, for convenience of description, the bottom surface 10B will be described.

The circumferential surface 10B may be configured to be detachably attached to the front face 10F, the object for using the space separating structure 10 (eg, the window or the wall 600, etc.) or both. Also, even if the circumference 10B is not further included, the circumference of the front face 10F (for example, the side, the bottom, etc.) may be detachably attached to the object (for example, the window or the wall 600) or both. It is possible. In addition, the circumferential surface 10B may or may not include holes or passage inlets intersecting with each other, such as the front face 10F, or may be implemented to allow dynamic selection. In addition, it will be readily understood that the circumferential surface 10B will not be limited in material or detailed structure. For example, when implementing the bottom (10B) horizontally may further include a detailed structure for flowing rain water naturally, when using the bottom (10B) as a space for placing things, such as flower pots, or provide more window lock function It will be readily understood that a rigid material may be advantageous and may further include materials and detailed structures for light control, light reflection, light collection, and the like.

In addition, the circumferential surface 10B may be implemented to be deformable. For example, the bottom surface 10B may be implemented to be swingable. This structure dynamically creates various factors such as the inclination of the bottom surface 10B and the distance between the front surface 10F and the window 600 and the size of the air holding space H formed by the space separating structure 10. It will be easy to understand. For example, if you want rain water to naturally flow down the window frame from the bottom (10B) to be discharged out, bevel the bottom (10B) as shown in the drawing, if you want to put a pot on the bottom (10B), the bottom (10B) is horizontal, It will be readily understood that if the spatial separation structure 10 is to be in close contact with the window 600, the bottom 10B should be made parallel to the wall. In this case, if the space separating structure 10 is to be further fixed, the base 10B may swing upwards to overlap with a portion of the front surface 10F, and it will be easily understood that the window locking function may be further provided. In addition, the above description is not limited to the dynamic implementation, and it will be easily understood that the embodiments may be implemented. It is also easy to understand that swing is just an example, and the method of dynamic implementation is not limited thereto. For example, the circumferential surface 10B may be folded deformation (see fan, bellows, etc.) similarly to the front face 10F.

Providing a space in which the space separation structure 10 can hold air has several advantages. One of them is that the passage itself connecting the two separate spaces provides a mitigating or buffering space between the two separate spaces. For example, chills in winter and heat in summer are alleviated in this space. Therefore, in winter, when the ventilation is less heat is taken away, and the cold or cold wind is prevented from entering in a hurry, the need for heating is reduced, and various problems caused by the user's reluctance to ventilate (e.g. indoor air pollution, increased room humidity). , Increased risk of disease, increased risk of mold development, etc.). In the summer, the sun heats the window 600, so allowing the front 10F to be spaced apart from the window 600 is more advantageous for blocking heat. It will be easy to understand that further use of the additional front (10F) will better prevent summer heat and drafts that invade the windows of the winter.

In addition, the user may further obtain additional space by the space separating structure 10. For example, this space can be utilized as a space for planting plants or hanging plants. Since plants help heat and moisture control, block dust or external gaze, and some plants also help to control pests, this can be used to further enhance the space separation structure 10 function.

Alternatively, you can use this space as a space to dry your laundry. This can be especially useful in buildings without verandas or terraces. It is not advisable to dry your laundry in your living space as it increases the humidity in your room. In addition, wind, air circulation, heat, sunlight, etc. are helpful for drying clothes, while outdoor drying is susceptible to dust, insects, rain, and the like. Therefore, it is advantageous to dry the laundry in the space provided by the space separation structure 10. In addition, it is more advantageous to arrange a helpful element such as a dehumidifying agent in the space or the space around the window or the space separating structure 10 itself. In particular, as described above, the present disclosure focuses on the window 600, but is not limited thereto, whereby the spatial separation structure 10 further includes additional elements, such as dehumidifiers, on or around it. (E.g., in food packaging or storage such as fruits, clothing, bags, etc.).

In addition, when the space separating structure 10 further includes a circumferential surface 10B, there are various advantages such as having an angle with the window 600, one of which is advantageous for light control. To further maximize these advantages, you can also include additional components for light control, components that utilize light, or both (eg mirrors, lenses, solar power elements, etc.).

In addition, one of the advantages that can be obtained by allowing the space separation structure 10 to completely wrap the opening 600 such as a window is improved security. Especially in the summer, the outsider's gaze or outsider's intrusion is a lot of problems. The prior art, as seen in the first figure, is easy to see outsiders when the wind is blowing, the spatial separation structure 10 according to an embodiment of the present invention also blocks these holes.

In addition, a conventional curtain or the like does not provide an intrusion prevention function, and the conventional window or door 600 may use the locking function only in a completely closed state. However, it will be readily understood that the space separating structure 10 according to an embodiment of the present invention may make intrusion of an outsider impossible or difficult even if the window 600 is open. Furthermore, the spatial separation structure 10 according to an embodiment of the present invention may further include a component that can lock the movement of the window 600 itself, and further, the window 600 may include the spatial separation structure 10. The embodiment that can be opened and closed through the component of) is also possible. Alternatively, a separate opening and closing system connected to the window 600 may be protected by the space separation structure 10 to prevent an intruder from operating from the outside. Since these embodiments may be implemented in a wide variety of ways, a detailed description is omitted (some components will be described later through other applications). That is, the space separating structure 10 according to an embodiment of the present invention locks the means for locking the space separating structure 10 itself and the object of use of the space separating structure 10 (eg, the window 600). It may further comprise one or more of the means that can.

The upper rightmost figure of FIG. 12 illustrates the above technique through another application. As described above, the spatial separation structure 10 may be implemented such that the front face 10F is spaced from the object of use, and this embodiment further provides additional advantages. In addition, the separation may be implemented to be provided by the circumferential surface 10B, in which case it is also possible to modify the circumferential surface 10B so that the separation property such as the separation degree, the separation angle, etc. can be changed. . In addition, although the foregoing description is omitted, this separation is not limited to the separation between the front surface 10F and the object to be used. According to the embodiment, the principle of separation by the deformation of the circumferential surface 10B may also be employed in the separation between one unit and the other unit. For example, it can be easily understood that the use of the folding deformation as a principle of controlling the separation distance as in the above-described example is applicable not only to the separation between the front surface 10F and another object but also to the separation between one unit and the other unit. will be. Therefore, in the present specification, for convenience, it is described as referring to the separation between the front surface 10F and another object, but it should be noted that it is not limited thereto. In clothing, for example, unlike the related art, when the clothes consisting of one side unit 100 and the other side unit 200 or the front side 10F and the additional front side 10F 'are connected to the folded seam 10B, the seam seam 10B The one side unit 100 and the other unit 200 or the front face 10F and the additional front face 10F 'are spaced apart from each other. This, in turn, has the effect of separating the body and the outer surface (100 or 10F) of the clothes (H). It will be readily understood that this will be particularly advantageous in summer or hot weather. It will also be appreciated that this application will not be limited to clothing. Also, it will be readily understood that the front face 10F, 10F ″ may be implemented to have no opening or to control opening and closing of the opening, or may be implemented to adjust the size of the passage as described above. For example, the outer surface 10F may include one or more holes that can be opened and closed.

For example, the drawings illustrate this effect through another application. It is a conceptual diagram of the bag which separated each other by connecting three front surfaces 10F, 10F ', and 10F "with the seam allowance 10B. As shown in the figure, there is a space H 'between the space H into which the article 600' can be placed and the front side 10F '' of the body side. The second spacing H 'makes the bag less warm when using the bag in the summer and prevents the article from getting wet, as in the example of clothing described above. It is also ventilated and provides air, so it also provides a drying function when the bag or item is wet. In addition to this function, the seam allowance 10B secures an appropriate first separation space H so that the object 600 'can be comfortably inserted and removed, and the object 600' is well supported to provide stability. In addition, the seam allowance 10B has an effect of supporting the bag 10 to be in close contact with the body. Furthermore, if the seam allowance 10B is implemented to be folded and deformable as described above, the size of one or more of the separation spaces H and H 'may also be adjusted, and the degree of ventilation and drying described above may also be adjusted. I can regulate it. In addition, as described above, the second separation space H 'may also be implemented to be opened and closed. This makes it possible to provide the same space separation structure 10 with the effect of improving the thermal insulation function by making the space holding air as opposed to summer in the winter.

The bottom first drawing of FIG. 12 describes an example of the components of the locking function described above through the application of a waistband. Conventional waistband is passed through a plurality of loops (600H) formed on the pants and then fastening the coupling means 43 at both ends to prevent the pants from falling down, and at this time the loop (600H) formed in the bag on the waistband Passing it through can also secure the bag to your pants. The problem is that the belt is not fixed in the state in which the coupling means 43 is released, so that the belt may be unintentionally dropped from the pants. In particular, when the bag is connected to the belt, the weight is likely to fall freely due to its weight. As a result, many users experience belts and bags falling off the toilet floor. In particular, in general, a bag that is connected to the waistband often contains valuables such as mobile phones and wallets, which can be particularly problematic.

The belt 400 according to one embodiment of the invention further comprises a self locking element 41. A fastening element in which one end 41F is fixed to the self-locking element 41 and the other end 41P is fastened to the self-locking element 41 again by turning one of the rings 600H formed on the object of use such as trousers. (42) is included. For example, when the belt 400 is used in place of a conventional waistband, if the belt 400 is fastened to the pants 600H by using the self-locking elements 41 formed at both ends of the belt 400, the target locking element 43 such as a buckle is provided. Even when the belt 400 is released, the belt 400 remains fixed to the object to be used (for example, pants). This ensures that not only the belt itself but also a fastening object (eg a bag) remains fixed to the use object (eg a pants). Further, according to the embodiment, the self-locking element 41 may be embodied to be able to change its position or to change the length of the fastening element 42, which embodiment is a hook 600H formed on the object to be used (eg, pants, etc.). It will be easy to understand that the implementation can better adapt to changes in the usage environment, such as the location of the. In addition, the implementation of the fastening element 42 is not limited. Furthermore, the self locking element 41 may be implemented with an existing object locking element (eg buckle 43 or the like). For example, an embodiment is also possible in which the fastening element 42 (eg, forming, detaching, connecting, etc.) is fastened to itself by turning the loop 600H of the pants to the buckle 43.

The bottom right view of FIG. 12 is an example of another locking element. It will be appreciated that the belt 400 described above is not limited to a belt. As with all other techniques herein, pants and waistbands are taken as examples for convenience of description. Likewise, the present locking element is not limited to the application or implementation, but it will be understood that it can be conveniently used for bag, curtain lock, sneaker strap, etc. for convenience. For example, when the space separating structure 10 according to an embodiment of the present invention is to be lifted or deformed, the state or position can be easily used.

The embodiment of the figure is an embodiment of simply locking the position or opening or closing through the fastening through the two bands. The two bands are fixed only to points 41F and 41F 'farthest from each other. The user fastens the points 41P and 41P 'closest to each other using a pruned knot. Since the Prune knot is a known knot method, detailed description thereof will be omitted. The band is preferably a material that provides more friction than a slippery material.

The above description of the present invention is intended for illustration, and it will be understood by those skilled in the art that the present invention may be easily modified in other specific forms without changing the technical spirit or essential features of the present invention. will be. Therefore, it should be understood that the embodiments described above are exemplary in all respects and not restrictive. For example, each component described as a single type may be implemented in a distributed manner, and similarly, components described as distributed may be implemented in a combined form.

The scope of the present invention is shown by the following claims rather than the above description, and all changes or modifications derived from the meaning and scope of the claims and their equivalents should be construed as being included in the scope of the present invention. do.

10: spatial separation structure
100: one side unit
200: the other unit

Claims (1)

At least one side unit separating the space into one side space and the first region;
And at least one other unit separating the space into the other space and the second area.
The one unit and the other unit are alternately arranged so that there is an overlapping part, the first area and the second area are connected to each other through a common area provided by the overlapping part,
The alternately arranged one side unit and the other unit separates the one side space and the other side space,
And a second region connected to the one space, the common region, and the first region connected to the other space to form a path of an object or a wave between the one space and the other space.

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