JP5748425B2 - Shutter - Google Patents

Description

The present invention relates to a sheet Yatta.

  The shutter ventilating device according to the first prior art urges a shutter panel formed by connecting a large number of horizontal slats in the vertical direction with play in a vertical direction by mechanical winding means and pulls down the shutter panel. Close by. The shutter ventilation device includes stop mechanisms that selectively stop the closed shutter panels at two locations, upper and lower, in the middle in the height direction. The ventilator for the shutter is provided with a vent hole in the slat connecting part below the stop mechanism, and when the shutter panel is stopped at the upper position, each slat below the stop position is moved away by its own weight. When the vent hole opens and stops at a lower position, the slats below the stop position operate in close proximity to close the vent hole (see, for example, Patent Document 1).

  The shutter according to the second prior art is provided with a winding spring that winds up the slat, an intermediate locking device is provided at an intermediate portion in the vertical direction of the slat, and a slat having a ventilation hole is provided below the lock lever of the intermediate locking device. The shutter has a ventilation function because the connected slats are provided with ventilation holes (see, for example, Patent Document 2).

JP-A-8-135341 JP-A-8-21167

  The shutter ventilating device according to the first prior art and the shutter according to the second prior art have a configuration in which sunlight passes through the vent hole, so that there is a problem that the room becomes hot due to the passing sunlight. In addition, if the ventilation holes are formed small in order to suppress the passage of sunlight, there is also a problem that ventilation and lighting characteristics deteriorate.

An object of the present invention is to provide a Cie Yatta it is possible to increase the shielding of the sunlight.

The present invention is a plurality of daylighting slats made of a light-shielding material, formed in a strip shape, and arranged side by side in the width direction perpendicular to the longitudinal direction with a predetermined interval, the thickness dimension and the predetermined interval However, when the width direction is the vertical direction, a plurality of daylighting slats are set to values that prevent parallel light having an angle of 31 ° or more upward with respect to the horizontal plane from passing through the gaps between the daylighting slats. A slat structure for daylighting including:
A light shielding slat structure including a plurality of light shielding slats made of a light shielding material, formed in a strip shape, and connected to each other adjacent to each other in a width direction perpendicular to the longitudinal direction;
The lighting slat structure and the shading slat structure are coupled in the width direction,
Wherein the width dimension of the lighting slat is rather smaller than the width dimension of the light shielding slat,
Each of the daylighting slats includes a connection part that connects the daylighting slats adjacent to each other so that the daylighting slats can expand and contract in the width direction, and the connection part has the predetermined interval of 0 mm. It is above and can be displaced below the set value,
The light shielding slats adjacent to each other are angularly displaced around the axis extending in the longitudinal direction between the widthwise end of one light shielding slat and the widthwise end of the other light shielding slat adjacent to the end. The shutter is connected in such a manner that it is possible and does not expand and contract in the width direction .

  Further, the present invention is characterized in that the daylighting slat has a thickness dimension of 7 mm and the predetermined interval is set to 4 mm.

Further, in the present invention, the daylighting slat structure is disposed above the light shielding slat structure,
In a building having an opening, the building is installed at a position covering an opening area defined by the opening from the outside of the building.

  Moreover, the present invention is characterized in that a lower end portion of the daylighting slat structure is disposed at a position of 1710 mm or more upward from a floor surface in the room of the building.

According to the present invention, the shutter includes a lighting slat structure and a light shielding slat structure. The daylighting slat structure includes a plurality of daylighting slats. The daylighting slat is made of a light-shielding material and is formed in a band shape. The plurality of daylighting slats are arranged side by side with a predetermined interval in the width direction perpendicular to the longitudinal direction. The plurality of daylighting slats have parallel thicknesses of 31 ° or more upward with respect to the horizontal plane when the thickness dimension and the predetermined interval are vertical in the width direction, and pass through the gaps between the daylighting slats. Is set to a value that prevents. The light shielding slat structure includes a plurality of light shielding slats. The light shielding slat is made of a light shielding material and is formed in a belt shape. The plurality of light shielding slats are connected to each other adjacent to each other in the width direction perpendicular to the longitudinal direction. The daylighting slat structure and the light shielding slat structure are connected in the width direction. The dimension in the width direction of the daylighting slat is smaller than the dimension in the width direction of the light shielding slat. Each of the daylighting slats includes a connecting portion that connects the daylighting slats adjacent to each other so that the daylighting slats can extend and contract in the width direction. The connecting portion is capable of displacing the predetermined interval to 0 mm or more and a set value or less. The light shielding slats adjacent to each other are angularly displaced around the axis extending in the longitudinal direction between the widthwise end of one light shielding slat and the widthwise end of the other light shielding slat adjacent to the end. They are connected in such a manner that they are possible and do not expand or contract in the width direction.

Thus, the daylighting slat structure allows ventilation and daylighting from the gap between the daylighting slats, for example, by installing the daylighting slat in an opening such as a window of the building. It can shield the solar radiation more than °. Therefore, it is possible to suppress an increase in indoor temperature due to sunlight passing through the air gap.
As a result, when the shutter is installed in an opening such as a window of the building, the external space and the internal space of the building are communicated with each other by a gap between the daylighting slats, and ventilation and ventilation are performed even when the shutter is closed. Daylighting can be enabled. Moreover, the shutter can block solar radiation with a solar altitude of 31 ° or more. Therefore, it is possible to suppress an increase in indoor temperature due to sunlight passing through the air gap.

Further , the daylighting slat structure can adjust the amount of air flow and the amount of light collected from the gaps between the daylighting slats while shielding solar radiation with a solar altitude of 31 ° or more. Moreover, if the space | interval predetermined by a connection part is set to 0 mm, the slat structure for lighting will become a structure by which a space | gap is not formed, and can improve a crime prevention effect.

  According to the present invention, the daylighting slat is formed to have a thickness dimension of 7 mm and a predetermined interval is set to 4 mm.

  Thereby, the predetermined interval is set to 4 mm in the daylighting slat structure, so that the child cannot insert a finger between the daylighting slats. Therefore, the daylighting slat structure can prevent a child from filling his / her finger in the gap between the daylighting slats. Therefore, the slat structure for daylighting can improve safety.

  According to the invention, the daylighting slat structure is disposed above the light shielding slat structure. In a building having an opening, the shutter is installed at a position that covers the opening area defined by the opening from the outside of the building.

  As a result, when the light shielding slat structure and the daylighting slat structure are heated by the solar radiation and the air in the opening region becomes hot, the shutter efficiently removes the hot air from the gap between the daylighting slats. It can be discharged well.

  Moreover, according to this invention, the lower end part of the slat structure for lighting is arrange | positioned upwards from the floor surface in the room | chamber interior of a building in the position of 1710 mm or more.

  Thereby, the shutter can block the view into the building from the outside of the building through the gap between the daylighting slats. Therefore, the shutter can suppress invasion of privacy in the room.

It is a front view which shows the shutter 1 which concerns on one Embodiment of this invention. It is the front view which expanded some shutters 1 shown in FIG. It is sectional drawing which cut | disconnected the shutter 1 shown in FIG. 2 by the cutting plane line III-III. FIG. 4 is a cross-sectional view of the shutter 1 shown in FIG. 2 cut along a cutting plane line IV-IV. FIG. 4 is a cross-sectional view of the shutter 1 stored in a storage box 24. It is a partial figure for demonstrating the usage condition of the shutter. FIG. 4 is another part of the diagram for explaining a usage mode of the shutter 1. It is a remaining figure for demonstrating the usage condition of the shutter. It is a graph which shows the solar radiation amount for every time of the day of the summer solstice. It is a figure for demonstrating the angle of the light which passes the space | gap 13 of the slat 6 for lighting. It is a graph which shows the solar radiation shielding limit time and aperture ratio when changing the space | interval D1 of the slat structure 2 for lighting. It is a figure for demonstrating the setting of the height dimension H2 of the slat structure 2 for lighting, and the height dimension H3 of the slat structure 3 for light shielding.

  FIG. 1 is a front view showing a shutter 1 according to an embodiment of the present invention. In FIG. 1, the vertical direction is indicated by the vertical direction Z, the horizontal direction is indicated by the second horizontal direction X, and the direction perpendicular to the second horizontal direction X and the vertical direction Z is indicated by Y as the first horizontal direction.

  In a building having an opening, the shutter 1 is installed at a position that covers an opening area defined by the opening from the outside of the building. The shutter 1 is slidably arranged in the vertical direction Z on the outdoor side of the opening formed on the outer wall of the building, so that the opening can be opened and closed. Buildings include, for example, houses, welfare facilities, accommodation facilities, commercial facilities, public facilities, and other buildings. The opening includes various windows such as a sweep window having a lower portion provided on the same plane as the floor.

  The shutter 1 is formed in a substantially rectangular plate shape when viewed from the first horizontal direction Y. The shutter 1 has a height dimension H1 in the vertical direction Z of 2383 mm, for example, and a width dimension W1 in the second horizontal direction X of, for example, 1725 mm. The maximum value of the dimension H1 is 2383 mm. The opening is formed with a height dimension H1 of 2383 mm, which is the same as the height dimension H1 of the shutter 1, for example, and the width dimension is slightly smaller than 1725 mm which is the width dimension W1 of the shutter 1.

  The shutter 1 includes the daylighting slat structure 2 and a light shielding slat structure 3. The daylighting slat structure 2 includes a plurality of daylighting slats 6. The lighting slat structure 2 is set to have a height dimension H2 of, for example, 418 mm.

  The plurality of daylighting slats 6 are made of a light-shielding material, such as aluminum, and are generally formed in a band shape. The plurality of daylighting slats 6 are arranged in such a posture that the longitudinal direction X of each daylighting slat 6 is substantially horizontal and the width direction Z perpendicular to the longitudinal direction X is substantially vertical. Substantially horizontal includes horizontal, and substantially vertical includes vertical.

  The plurality of daylighting slats 6 have a thickness T1 dimension of each daylighting slat 6 and a predetermined interval D1 of 31 ° upward with respect to the horizontal plane in a state where the width direction and the vertical direction Z of the daylighting slats 6 coincide with each other. It is set to a value that prevents parallel light such as sunlight having the above angle from passing through the gap 13 between the daylighting slats 6.

  The light shielding slat structure 3 includes a plurality of light shielding slats 7. The light shielding slat structure 3 has a height dimension H3 set to, for example, 1965 mm. The plurality of light shielding slats 7 are made of a light shielding material, for example, iron, and are generally formed in a belt shape. The plurality of light shielding slats 7 have the same posture as the daylighting slats 6, that is, postures in which the longitudinal direction X of each light shielding slat 7 is substantially horizontal and the width direction Z perpendicular to the longitudinal direction X is substantially vertical. Are connected to each other adjacent to each other in the width direction Z.

  The lighting slat 6 and the light shielding slat 7 that are adjacent to each other in the vertical direction Z are respectively formed with connecting portions 17 that connect the vertical direction Z to each other. The daylighting slat structure 2 is disposed above the light shielding slat structure 3. The lower end portion of the lighting slat structure 2 in the vertical direction Z is disposed at a position of 1710 mm or more upward from the floor surface in the room of the building.

  In the opening, guides 11 formed on both sides in the second horizontal direction X of the opening and supporting both ends of the shutter 1 in the second horizontal direction X are formed. Each guide 11 supports the shutter 1 so as to be slidable in the vertical direction Z. The shutter 1 is movable in the vertical direction Z while maintaining the posture in which the width directions of the daylighting slats 6 and the light shielding slats 7 coincide with the vertical direction Z.

  In the shutter 1, regions having a predetermined dimension W <b> 2 in the second horizontal direction X, for example, 32.5 mm, are arranged in the guide 11 at both ends in the second horizontal direction X. Therefore, the inner dimension W3 of the guide 11 in the second horizontal direction X is 1660 mm.

  FIG. 2 is an enlarged front view of a part of the shutter 1 shown in FIG. The lighting slat 6 is formed in a hollow rectangular parallelepiped shape by a metal plate. The slat 6 for daylighting is formed such that a dimension W1 in the longitudinal direction X is, for example, 1725 mm, a dimension H4 in the width direction that is the vertical direction Z is, for example, 16 mm, and a dimension T1 in the thickness direction Y is, for example, 7 mm. The daylighting slats 6 are arranged side by side in the vertical direction Z with a predetermined interval D1 in the vertical direction Z, for example, 4 mm. A gap 13 is formed between the vertical directions Z of the daylighting slats 6.

  Each of the daylighting slats 6 is formed with a connecting portion 16 for connecting the daylighting slats 6 adjacent to each other at the end in the width direction Z of the daylighting slat 6. In the present embodiment, the daylighting slats 6 are connected to each other by the connecting portion 16.

  The light shielding slat 7 is formed of a metal plate. For example, the light shielding slat 7 is formed such that the dimension W1 in the longitudinal direction X is 1725 mm, for example, and the dimension H5 in the width direction Z is 40.6 mm.

  The shutter 1 is formed with a connecting portion 17a for connecting the adjacent light shielding slats 7 to each other, and a connecting portion 17b for connecting the adjacent daylighting slats 6 and the light shielding slats 7 to each other. The connecting portion 17a and the connecting portion 17b are collectively referred to simply as “connecting portion 17”. The connecting portion 17 is formed at the end in the width direction Z of the light shielding slat 7 or the daylighting slat 6.

  3 is a cross-sectional view of the shutter 1 shown in FIG. 2 cut along a cutting plane line III-III. 4 is a cross-sectional view of the shutter 1 shown in FIG. 2 cut along a cutting plane line IV-IV. The shutter 1 shown in FIGS. 3 and 4 has a configuration in which a light shielding slat 7 is further added to the shutter 1 shown in FIG. 2, and the added light shielding slat 7 is perpendicular to the lighting slat structure 2. It is connected above the direction Z.

  FIGS. 3A and 4A show a state in which the daylighting slat structure 2 is contracted in the vertical direction Z, and FIGS. 3B and 4B show the daylighting slat structure. 2 shows a state of extending in the vertical direction Z.

  The connection part 16 is comprised by the connection recessed part 16a and the connection convex part 16b. The connection recess 16 a is formed at the lower end of the lighting slat 6 in the vertical direction Z, and defines a recessed space that opens downward in the vertical direction Z. The connection convex portion 16b is formed at the upper end portion in the vertical direction Z of the daylighting slat 6 so as to face upward in the vertical direction Z.

  The connection portion 16 holds the lighting slats 6 so as to be extendable and contractable in the vertical direction Z by the connection recesses 16a and the connection projections 16b engaging with the connection projections 16b inserted into the connection recesses 16a. . The connection part 16 can displace the space | interval D1 between each lighting slat 6 to 0 mm or more and the said preset value, for example, 4 mm or less. A plurality of gaps 13 are formed in the second horizontal direction X on the lower side of the connecting projection 16b in the vertical direction Z. The gap 13 includes a horizontally long rectangular through hole formed at a plurality of, for example, eight equally spaced intervals in the second horizontal direction X and a horizontally long rectangular cut formed at both ends of the second horizontal direction X. The dimension of the gap 13 in the vertical direction Z is the same as D1. The dimension W4 in the second horizontal direction X of the connection convex portion 16b where the gap 13 is not formed and the position in the vertical direction Z coincides with the position of the gap 13 is, for example, 8 mm. The connecting portion 16 holds the daylighting slats 6 so as to be angularly displaceable with the axis as the second horizontal direction X.

  The connecting portion 17 a connects the adjacent light shielding slats 7, and the connecting portion 17 b connects the light shielding slats 7 and the daylighting slats 6.

  The connecting portion 17a is formed by engaging both end portions of the plate shape with each other at the end portions of the adjacent light shielding slats 7 in the vertical direction Z. The connecting portion 17a connects the light shielding slats 7 so as to be angularly displaceable with the second horizontal direction X as an axis.

  The lighting slat 6 is formed with a plate-like body extending in the vertical direction Z at the upper end or the lower end in the vertical direction Z adjacent to the light shielding slat 7. The connecting portion 17 b is formed by winding and engaging both plate-like end portions at the end portions of the adjacent light shielding slats 7 and the daylighting slats 6. The connecting portion 17b connects the shading slat 7 and the lighting slat 6 so as to be angularly displaceable with the axis line as the second horizontal direction X.

  FIG. 5 is a cross-sectional view of the state in which the shutter 1 is stored in the storage box 24. The storage box 24 is fixed to the outer wall 21 on the outdoor side at a position above the opening 22 of the building. The storage box 24 winds and stores the shutter 1. In FIG. 5, the shutter 1 has a configuration in which a light shielding slat 7 is connected below the daylighting slat 6 and a seat plate 23 is connected below the light shielding slat 7.

  The storage box 24 includes a housing 25, a winding drum 26, and a motor 27. The housing 25 is formed of a plate-like member such as metal or resin. The casing 25 is generally formed in a rectangular parallelepiped shape, and the winding drum 26 and the motor 27 are disposed inside. The housing 25 is fixed to the outer wall 21.

  A housing opening 29 is formed at the lower end of the housing 25. The upper end of the guide 11 in the vertical direction Z is inserted into the housing opening 29. The winding drum 26 is generally formed in a cylindrical shape. The winding drum 26 is arranged with its axis line in the second horizontal direction X. A light-shielding slat 7 disposed at the uppermost end of the shutter 1 is connected to the winding drum 26.

  The motor 27 is connected to the winding drum 26 by a power transmission belt (not shown), and rotates the winding drum 26. When the winding drum 26 is driven to rotate, the shutter 1 can be opened and closed at the opening 22.

  FIG. 6 is a partial view for explaining how the shutter 1 is used. FIG. 7 is another part of the view for explaining the usage mode of the shutter 1. FIG. 8 is a remaining diagram for explaining a usage mode of the shutter 1. 6, 7 and 8 show a state in which the window 31 is viewed from the room. The window 31 is a sweep window installed at the opening of the outer wall 21 and includes a window frame 32 and a window glass 33.

  FIG. 6A is a diagram illustrating the shutter 1 in the fully open state which is the first state. In the first state, all of the shutter 1 is stored in the storage box 24. Accordingly, all of the opening region 34 defined by the window frame 32 is in an open state, that is, the shutter 1 does not cover the window 31, and sunlight can be irradiated from the window 31 into the room.

  FIG. 6B is a diagram illustrating the shutter 1 in the lower open state that is the second state. This second state is a state where the shutter 1 is lowered from the first state, and about half of the shutter 1 is closed. The light shielding slat structure 3 covers the upper half of the window 31.

  FIG. 7A is a diagram showing the shutter 1 in the upper and lower open states that are the third state. The third state is a state in which the shutter 1 is further lowered from the second state. The lighting slat structure 2 covers an upper end portion of the window 31 in the vertical direction Z, and the light shielding slat structure 3 covers a central portion between both ends of the window 31 in the vertical direction Z. The lower end portion of the window 31 in the vertical direction Z is in an open state.

  FIG. 7B is a diagram illustrating the shutter 1 in the upper open state that is the fourth state. The fourth state is a state in which the shutter 1 is further lowered from the third state. The lighting slat structure 2 covers the upper end of the window 31. The connecting portion 16 can be expanded and contracted in the vertical direction Z, and extends downward in the vertical direction Z by the weight of the shutter 1 to hold the interval between the daylighting slats 6 at a predetermined value. The light shielding slat structure 3 covers the center and the lower end of the window 31 in the vertical direction Z.

  FIG. 8A is a diagram illustrating the shutter 1 in the upper closed state which is the fifth state. The fifth state is a state in which the shutter 1 is further lowered from the fourth state. The lighting slat structure 2 covers the upper end of the window 31. In the lighting slat structure 2, in the upper half of the upper end portion of the window 31, the connecting portion 16 extends to maintain the interval between the lighting slats 6 at a predetermined value. In the lower half of the vertical direction Z, the connecting portion 16 contracts to maintain the distance between the daylighting slats 6 at 0 mm. The shading slat structure 3 covers the center and the lower end of the window 31.

  FIG. 8B is a diagram illustrating the shutter 1 in the fully closed state that is the sixth state. The sixth state is a state in which the shutter 1 is further lowered from the fifth state. The lighting slat structure 2 covers the upper end of the window 31. In the upper end portion of the window 31, the lighting slat structure 2 is such that all of the connecting portions 16 are contracted, and the interval between the lighting slats 6 is maintained at 0 mm. The shading slat structure 3 covers the center and the lower end of the window 31.

FIG. 9 is a graph showing the amount of solar radiation for each time of the summer solstice. In the graph of FIG. 9, the vertical axis indicates the amount of solar radiation (W / m ² ), and the horizontal axis indicates time. In this graph, the curve A1 represents the amount of solar radiation on the horizontal plane, the curve A2 represents the amount of solar radiation on the east surface, which is the east-facing vertical surface, and the curve A3 represents the amount of solar radiation on the west surface, which is the west-facing vertical surface. The curve A4 represents the amount of solar radiation on the south surface, which is the south-facing vertical surface, and the curve A5 represents the amount of solar radiation on the north surface, which is the north-facing vertical surface.

  In a house, room temperature rises when the sunshine is irradiated indoors. Therefore, it is required to shield the sunshine near the time indicating the maximum value of the amount of sunshine on the west. Curve A3 indicates the amount of solar radiation near the maximum at the time from 15:00 to 16:30.

  Table 1 shows the solar altitude for each day of the summer solstice. It can be seen that in order for the daylighting slat structure 2 to block solar radiation from 15:00 to 16:30, it is only necessary to shield solar radiation with a solar altitude of 31 ° or more. The data in Table 1 and FIG. 9 are data at a solar radiation amount of 35 degrees north latitude and an atmospheric transmittance of 0.7.

  FIG. 10 is a view for explaining the angle of light passing through the gap 13 of the daylighting slat 6. FIG. 10A shows a cross-sectional view of the daylighting slat 6, and FIG. 10B shows an enlarged view of the gap 13 of the daylighting slat 6 shown in FIG.

  The daylighting slats 6 are formed with a thickness dimension of T1 and a width dimension of H4, and the daylighting slats 6 are arranged with a gap D1 in the vertical direction Z. A gap 13 is formed between the daylighting slats 6. The angle θ of the parallel light passing through the gap 13 is represented by “tan θ = D1 / T1”.

  Table 2 shows the relationship between the thickness [theta] 1 and the distance D1 of the daylighting slat 6 and the angle [theta]. From Table 2, the values of the thickness dimension T1 and the distance D1 of the daylighting slat 6 necessary for shielding solar radiation with a solar altitude of 31 ° or more, that is, passing only solar radiation with a solar altitude of 0 ° or more and less than 31 ° are obtained.

  FIG. 11 is a graph showing the solar radiation shielding limit time and the aperture ratio when the interval D1 of the daylighting slat structure 2 is changed. In the graph of FIG. 11, the left vertical axis indicates time, the right vertical axis indicates the aperture ratio, and the horizontal axis indicates the length of the interval D1.

  In the example shown in FIG. 11, the daylighting slat structure 2 is formed such that a dimension H2 in the vertical direction Z is 400 mm. The daylighting slat structure 2 has a thickness dimension T1 of 7 mm and a width dimension H4 of 16 mm. The daylighting slat structure 2 is formed such that the dimension W1 in the longitudinal direction X is larger than the inner dimension in the second horizontal direction X of the opening of the building.

The distance D1 between the daylighting slat structures 2 is set from the following viewpoints (1) to (3).
(1) Viewpoint of solar radiation shielding The solar radiation shielding limit time indicates a time when the daylighting slat structure 2 can shield solar radiation, and is represented by a line segment B1. For example, the line segment B1 represents that the solar radiation before about 16:35 can be shielded when the distance D1 between the daylighting slats 6 is 4 mm. As described above, since the daylighting slat structure 2 needs to shield solar radiation from 15:00 to 16:30, the interval D1 is preferably 4 mm or less.

(2) Viewpoint of aperture ratio The aperture ratio refers to the area of the plate-like portion of the daylighting slat structure 2 and the shading slat structure 3 in the state where the gap 13 is opened, as viewed from the first horizontal direction Y. The ratio of the area of the gap 13 is expressed as a percentage, and is represented by a line segment B2. For example, the line segment B2 shows an aperture ratio of about 2.7% when the distance D1 between the daylighting slats 6 is 4 mm. The daylighting slat structure 2 can exhibit high daylighting and ventilation when the aperture ratio increases. Therefore, in order to increase the aperture ratio, the interval D1 is preferably set to a large value.

(3) Viewpoint of safety Since the lighting slat structure 2 can be extended in the vertical direction Z by the connecting portion 16, the distance D1 may be 0 mm. Therefore, in order to prevent children's finger filling, the distance D1 between the daylighting slat structures 2 is preferably 5 mm or less.

  From these viewpoints (1) to (3), the daylighting slat structure 2 is most preferably set to have a distance D1 of 4 mm when the thickness dimension T1 is 7 mm.

  The daylighting slat structure 2 has a thickness T1 equal to that of the light-shielding slat 7, so that the winding diameter of the shutter composed of only the light-shielding slat 7 in the winding process of the winding drum 26 is as follows. Considering not to change extremely compared to the winding diameter, the winding diameter is made small and the wound shape is determined to approach a perfect circle. Further, by making the width dimension H4 of the daylighting slat structure 2 smaller than the width of the light shielding slat 7, the number of angularly displaceable connecting portions 16 corresponding to joints is increased, and in the process of winding on the winding drum 26. The winding diameter is determined so as not to change drastically as compared with the winding diameter of the shutter composed only of the light shielding slats 7, so that the winding diameter is reduced and the wound shape approaches a perfect circle. . In addition, the width dimension H4 is determined in consideration of other complex elements such as the connection portion 16 between the daylighting slats 6 and the outer shape that follows the winding.

  FIG. 12 is a diagram for explaining the setting of the height dimension H2 of the daylighting slat structure 2 and the height dimension H3 of the light shielding slat structure 3. As shown in FIG.

  In the example shown in FIG. 12, the shutter 1 has a height dimension H1 set to 2273 mm and a relationship of “H1 = H2 + H3”. The length ΔL in the vertical direction Z between the indoor floor surface 37 and the outdoor ground surface 38 is assumed to be 593 mm. The outdoor height dimension H6 that is the length from the ground 38 to the lower end of the daylighting slat 6 is calculated by “H6 = H3 + ΔL”.

  Table 3 shows the relationship between the height dimension H2 of the daylighting slat structure 2, the outdoor height dimension H6, and the height dimension H3 of the shading slat structure 3.

  The height dimension H2 of the daylighting slat structure 2 is set from the following viewpoints (4) and (5).

(4) Viewpoint blocking view The average height of Japanese is about 171 cm for men and about 158 cm for women. When the height dimension H3 of the light shielding slat structure 3 is set to a value of 171 cm or more, a person in the room is visually recognized from the outside through the gap 13 in a state where a person stands on the floor surface 37 in the room. Can be prevented. Therefore, when the height dimension H1 of the shutter 1 is set to 2273 mm, the height dimension H3 of the shading slat structure 3 is “H3 ≧ 1710 (mm)” and the height of the lighting slat structure 2 is high. The dimension H2 is preferably “H2 ≦ 563 (mm)”.

(5) Viewpoint of dimension of existing storage box 24 When the height dimension H1 of the shutter 1 is set to 2273 mm and the height dimension H2 of the daylighting slat structure 2 is formed to 400 mm, the shutter 1 The winding diameter is about 160 mm, which is smaller than 193 mm, which is the inner dimension of the existing storage box 24 in the first horizontal direction Y. When the height dimension H2 of the daylighting slat structure 2 is increased by 100 mm, the winding diameter of the shutter 1 is increased by 15 mm. Therefore, in order to be able to store the shutter 1 in the existing storage box 24, it is preferable to set the height dimension H2 of the lighting slat structure 2 to 400 mm or less. In order to increase the aperture ratio, it is preferable to increase the height dimension H2 of the daylighting slat structure 2.

  From the viewpoints of (4) and (5), when the height dimension H1 of the shutter 1 is 2273 mm, the height dimension H2 of the daylighting slat structure 2 is most preferably set to 400 mm. As described above, when the height dimension H1 of the shutter 1 is 2383 mm, it is most preferable that the height dimension H2 of the lighting slat structure 2 is set to 418 mm.

  Thus, the lighting slat structure 2 includes a plurality of lighting slats 6. The daylighting slat 6 is made of a light shielding material and is formed in a band shape. The plurality of daylighting slats 6 are arranged side by side with a predetermined interval in the width direction Z perpendicular to the longitudinal direction X. The plurality of daylighting slats 6 are parallel light beams having a thickness dimension T1 and a predetermined interval D1 of 31 ° or more upward with respect to the horizontal plane when the width direction is the vertical direction Z. The value is set to prevent passage through the gap 13.

  Thereby, the lighting slat structure 2 enables ventilation and lighting from the gap 13 between the lighting slats 6 by installing the lighting slat 6 in the opening 22 such as the window 31 of the building, for example. Furthermore, it is possible to shield solar radiation with a solar altitude of 31 ° or more. Therefore, it is possible to prevent the indoor temperature from rising due to sunlight passing through the gap 13.

  Each of the daylighting slats 6 includes at least one connecting portion 16 that connects the daylighting slats 6 adjacent to each other at the end in the width direction Z of the daylighting slat 6. The connection part 16 can displace the predetermined space | interval to 0 mm or more and below the set value.

  Thus, the daylighting slat structure 2 can adjust the air flow rate and the amount of light collected from the gaps 13 between the daylighting slats 6 while shielding at least solar radiation having a solar altitude of 31 ° or more. Moreover, if the predetermined space | interval is made zero by the connection part 16, the slat structure 2 for lighting will become the structure in which the space | gap 13 is not formed, and can improve a crime prevention effect.

  The daylighting slat 6 is formed to have a thickness dimension of 7 mm, and a predetermined interval is set to 4 mm.

  Thus, the daylighting slat structure 2 has a predetermined interval of 4 mm, so that the child cannot insert a finger between the daylighting slats 6. Therefore, the daylighting slat structure 2 can prevent a child from filling his / her finger in the gap 13 between the daylighting slats 6. Therefore, the lighting slat structure 2 can improve safety.

  The shutter 1 includes a daylighting slat structure 2 and a light shielding slat structure 3. The light shielding slat structure 3 includes a plurality of light shielding slats 7. The light shielding slat 7 is made of a light shielding material and is formed in a strip shape. The plurality of light shielding slats 7 are connected to each other adjacent to each other in the width direction Z perpendicular to the longitudinal direction X. The daylighting slat structure 2 and the light shielding slat structure 3 are connected in the width direction Z.

  Accordingly, when the shutter 1 is installed in the opening 22 such as the window 31 of the building, the external space and the internal space of the building are communicated with each other by the gap 13 between the daylighting slats 6 and the shutter 1 is closed. Even so, ventilation and lighting can be made possible. Moreover, the shutter 1 can shield the solar radiation with a solar altitude of 31 ° or more. Therefore, it is possible to prevent the indoor temperature from rising due to sunlight passing through the gap 13.

  The daylighting slat structure 2 is arranged above the light shielding slat structure 3. In a building having an opening 22, the shutter 1 is installed at a position that covers the opening area defined by the opening 22 from the outside of the building.

  Thereby, when the light shielding slat structure 3 and the daylighting slat structure 2 are heated by the solar radiation and the air in the opening region becomes high temperature, the shutter 1 causes the high temperature air to pass between the daylighting slats 6. It is possible to efficiently discharge from the gap 13.

  Moreover, the lower end part of the vertical direction Z of the slat structure 2 for lighting is arrange | positioned upwards from the floor surface 37 in the room | chamber interior of a building in the position of 1710 mm or more.

  Thereby, the shutter 1 can block the view into the building from the outside of the building through the gap 13 between the lighting slats 6. Therefore, the shutter 1 can suppress invasion of privacy indoors.

DESCRIPTION OF SYMBOLS 1 Shutter 2 Daylighting slat structure 3 Light-shielding slat structure 6 Daylighting slat 7 Light-shielding slat 11 Guide 13 Space | gap 16 Connection part 17 Connection part 21 Outer wall 22 Opening part 23 Seat plate 24 Storage box 25 Case 26 Winding drum 27 Motor 29 Housing opening 31 Window 32 Window frame 33 Window glass 34 Opening area 37 Floor surface 38 Ground

Claims (4)

A plurality of daylighting slats made of a light-shielding material, formed in a strip shape, and arranged side by side with a predetermined interval in the width direction perpendicular to the longitudinal direction, wherein the thickness dimension and the predetermined interval are in the width direction For daylighting including a plurality of daylighting slats set to a value that prevents parallel light that forms an angle of 31 ° or more upward with respect to the horizontal plane when passing through the gap between the daylighting slats. A slat structure;
A light shielding slat structure including a plurality of light shielding slats made of a light shielding material, formed in a strip shape, and connected to each other adjacent to each other in a width direction perpendicular to the longitudinal direction;
The lighting slat structure and the shading slat structure are coupled in the width direction,
Wherein the width dimension of the lighting slat is rather smaller than the width dimension of the light shielding slat,
Each of the daylighting slats includes a connection part that connects the daylighting slats adjacent to each other so that the daylighting slats can expand and contract in the width direction, and the connection part has the predetermined interval of 0 mm. It is above and can be displaced below the set value,
The light shielding slats adjacent to each other are angularly displaced around the axis extending in the longitudinal direction between the widthwise end of one light shielding slat and the widthwise end of the other light shielding slat adjacent to the end. A shutter that is connected in a form that can be expanded and contracted in the width direction . 2. The shutter according to claim 1 , wherein the daylighting slat is formed to have a thickness of 7 mm and the predetermined interval is set to 4 mm. The daylighting slat structure is disposed above the light shielding slat structure,
3. The shutter according to claim 1, wherein, in a building having an opening, the shutter is installed at a position covering an opening region defined by the opening from the outside of the building. The lower end of the daylighting slat structure is 1710 mm upward from the floor of the building interior.
The shutter according to claim 3 , wherein the shutter is disposed at the above position.

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