KR102551843B1 - kinetic louver unit, kinetic louver module, and kinetic louver apparatus including the same - Google Patents

Abstract

A kinetic louver unit is disclosed. The kinetic louver unit of the present invention includes a support frame installed near the ceiling so as to be supported on the ceiling of the building; A first louver frame portion disposed below the support frame; A second louver frame part disposed below the support frame and connected to the first louver frame part so that one end portion connected to the first louver frame part is hinge-rotatable; And with respect to the support frame, the first louver frame part, the second louver frame part, and the hinge connection part of the first louver frame part and the second louver frame part are driven up and down, individually controllable up and down drive Characterized in that it comprises a lifting and lowering drive unit. According to the present invention, by providing a damper, first and second contact supports, when vibrations occur in a building due to earthquakes or other factors, these vibrations are transmitted to the kinetic louver module to prevent safety accidents from occurring in advance. there is.

Description

Kinetic louver unit, kinetic louver module and kinetic louver device including the same {kinetic louver unit, kinetic louver module, and kinetic louver apparatus including the same}

The present invention relates to a kinetic louver unit, a kinetic louver module, and a kinetic louver device including the same, which are installed on the ceiling of a building and can produce various planned motions.

Kinetic art is an art based on movement. Kinetic art can be realized as mechanical operation powered by air flow or motor by giving mechanical engineering movement to a still sculpture. It's an art genre you're doing.

Kinetic art is a moving art work that draws people's attention, can maximize movement according to the effects of materials and light, and is actively used in advertisements, brand promotion, exhibitions, public sculptures, performances, etc. in combination with media art of other genres. It is being utilized.

Most of the movement of kinetic art devices is controlled by the artist who produces the kinetic art or controlled through a program, and the artist or developer designs the movement for this purpose.

These kinetic art devices are installed and utilized in places in various fields, and are currently applied to louvers of buildings as an example to provide people with a dynamic sense of aesthetics.

On the other hand, in order to meet people's expectations for acquiring a sense of aesthetics that gradually rise, it is required to develop a kinetic art device capable of providing kinetic motion with a higher degree of freedom than the present. In order to implement a kinetic motion with a higher degree of freedom due to its characteristics, the coupling structure of the motion unit and the drive unit that drives the movement of the motion unit is inevitably complicated and the manufacturing cost is inevitably increased.

Therefore, the applicant of the present invention develops and proposes a structure capable of directing kinetic motion having a higher degree of freedom than a certain level without significantly increasing cost.

Republic of Korea Patent Registration No. 10-1402661 (2014.06.03 announcement)

The present invention has been made to solve the above-mentioned conventional problems, and a kinetic louver unit and kinetic louver capable of providing kinetic motion with a sufficiently higher degree of freedom than before without significantly increasing manufacturing cost by adding a complicated structure. Its object is to provide a module and a kinetic louver device including the same.

According to one aspect of the present invention, a support frame provided near the ceiling; A first louver frame portion disposed below the support frame; A second louver frame part disposed below the support frame and connected to the first louver frame part so that one end portion connected to the first louver frame part is hinge-rotatable; And with respect to the support frame, the first louver frame part, the second louver frame part, and the hinge connection part of the first louver frame part and the second louver frame part are driven up and down, individually controllable up and down drive A kinetic louver unit including a lifting and lowering driving unit is provided.

The lifting and lowering driving unit connects between the support frame and the first louver frame unit, and winds or unwinds the first wire and the first wire connected to the first louver frame unit and is installed on the support frame a first lifting and lowering driving unit having a first wire winding unit; Connecting between the support frame and the second louver frame part, winding or unwinding the second wire and the second wire connected to the second louver frame part and having a second wire winding part installed in the support frame a second lifting and lowering driving unit; And connecting between the support frame and the hinge connection part of the first and second louver frame parts, and winding or unwinding the third wire and the third wire connected to the hinge connection part of the first and second louver frame parts and a third lifting and lowering driving unit having a third wire winding unit installed on the support frame.

The first louver frame part and the second louver frame part each have a louver frame having a length of more than a predetermined length; A plurality of LEDs installed on the louver frame; And a light emitting control unit installed on the louver frame and controlling light emission of the plurality of LEDs, wherein the third lifting and lowering driving unit supplies power to the plurality of LEDs of the first louver frame unit and the second louver frame unit, A power supply and communication line for transmitting and receiving a control signal with the light emitting control unit may be further included.

The third wire winding unit may simultaneously wind or unwind the power supply and communication lines to correspond to winding or unwinding of the third wire.

Each of the first louver frame unit and the second louver frame unit may further include a light diffusing unit coupled to the louver frame and diffusing light emitted from the LED.

The first louver frame part and the second louver frame part, respectively, the first louver frame part and the second louver frame part are connected to each other in the longitudinal direction to be retractable or withdrawable from each other disposed adjacently along the longitudinal direction, so that the entire It includes a plurality of unit louver frame parts that can increase or decrease in length, and each of the plurality of unit louver frame parts is disposed spaced apart from each other and can be drawn in or drawn out from each other in the longitudinal direction disposed adjacent to each other along the longitudinal direction. A pair of unit louver frames provided to do; And it may include a connection bracket connecting the pair of unit louver frames.

Each of the unit louver frames may have an elliptical cross-sectional shape through which an inside is penetrated.

Each of the unit louver frames is made of a shape with an inside penetrated, and a plurality of guide grooves spaced apart from each other are continuously provided along the longitudinal direction on the outer surface, and a plurality of guide grooves are continuously provided on the inner surface along the longitudinal direction to correspond to the plurality of guide grooves. The guide protrusions may be continuously provided.

The unit louver frame is made of a shape through which the inside is penetrated, and from the unit louver frame located near the hinge connection part, which is one end of each of the first louver frame part and the second louver frame part, toward the unit louver frame located at the other end It may be made so that the cross-sectional area gradually decreases gradually.

According to another aspect of the present invention, the module support frame provided near the ceiling; And there is provided a kinetic louver module including a plurality of kinetic louver units installed spaced apart from each other in the transverse direction with respect to the module support frame.

Each of the plurality of kinetic louver units may further include a connecting shaft connecting the hinge connection parts of the second louver frame parts to each other to enable simultaneous driving.

According to another aspect of the present invention, a plurality of dampers are fixedly installed and spaced apart from each other on a ceiling wall of a building to absorb external vibration; a plurality of first contact support units integrally provided below each of the dampers; kinetic louver module; And there is provided a kinetic louver device including a plurality of second contact support parts coupled to the plurality of first contact support parts on the upper side of the module support frame of the kinetic louver module.

Further comprising an elevation unit capable of moving the module support frame up and down between a ceiling and a floor of a building, and the plurality of second contact support units can be separated from or combined with the plurality of first contact support units by driving the elevator unit, , The plurality of first contact support parts and the plurality of second contact support parts may be respectively provided with in-position coupling inducing units for inducing in-position coupling with each other.

The fixed-position coupling guide portion may include a conical first coupling protrusion or first coupling groove provided on the second contact support portion; And a second conical coupling groove provided in the first contact support portion so that the first coupling protrusion can be inserted, or a conical second coupling groove provided in the first contact support portion so as to be inserted into the first coupling groove. It may contain coupling protrusions.

According to the kinetic louver unit, kinetic louver module, and kinetic louver device including the same of the present invention described above, by providing a damper, first and second contact supports, when vibration occurs in a building due to earthquake or other factors, such vibration It is delivered to this kinetic louver module to prevent safety accidents from occurring.

In addition, as the second contact support part is made of a structure that can be separated or combined with the first contact support part, the kinetic louver module can be lowered to the ground when repair or parts replacement of the kinetic louver module is required, so that the operator can easily work on the ground. Therefore, it has advantages in terms of safety accident prevention and maintenance during work.

In addition, by providing the first contact support portion and the second contact support portion, each of which is provided with a coupling induction unit for inducing in-place coupling with each other, it is possible to quickly and easily induce in-position coupling of the first contact support portion and the second contact support portion. can

In addition, by providing a hinge connection between the first louver frame unit and the second louver frame unit and individually controlling the driving of the first to third lift drivers, it is possible to provide a kinetic motion with a much higher degree of freedom than before.

In addition, the first louver frame part and the second louver frame part each include a plurality of unit louver frame parts disposed adjacently along the longitudinal direction to be retractable or retractable in the longitudinal direction, thereby increasing the overall length. By being made of a structure that can be reduced or reduced, there is an advantage in that it is particularly easy to store and transport.

In addition, a plurality of unit louver frames continuously connected along the longitudinal direction of the first louver frame part and the second louver frame part are formed in a form in which the elliptical cross-sectional area gradually decreases from one side to the other, By gradually reducing the applied load, it is possible to prevent deterioration of structural stability due to downward deflection of the free end.

In addition, since the third lift driver includes a power supply and a communication line, compared to a structure in which the first lift driver and the second lift driver each include a power supply and a communication line, the first lift driver and the second lift driver respectively. By simplifying the structure of the lifting and lowering drive unit, cost can be reduced and LED light emission can be controlled more efficiently.

1 is a perspective view showing a kinetic louver device according to an embodiment of the present invention;
2 is a side view showing a state in which a kinetic louver device according to an embodiment of the present invention is installed;
3(a) is a right side view of FIG. 2 and FIG. 3(b) is a view in which the connecting shaft is omitted;
4 is a view showing a state in which the kinetic louver module rises and falls in the kinetic louver device according to an embodiment of the present invention;
5 is a diagram showing various kinetic motions of a kinetic louver module in a kinetic louver device according to an embodiment of the present invention;
6 is a perspective view showing a kinetic louver unit according to an embodiment of the present invention;
Figure 7 is an enlarged view of a portion of Figure 6;
8 is a cross-sectional view of a first louver frame part or a second louver frame part in a kinetic louver unit according to an embodiment of the present invention;
9 is a view showing a state in which an LED and a light diffusing unit are installed between a unit louver frame and a connection bracket in a kinetic louver unit according to an embodiment of the present invention;
10 is a view showing a first louver frame part or a second louver frame part of a kinetic louver unit according to an embodiment of the present invention;
11 is a view showing a state in which the length of the first louver frame part or the second louver frame part of the kinetic louver unit according to an embodiment of the present invention is adjusted in the longitudinal direction;
12 is a view showing that a unit louver frame unit is inserted into another unit louver frame unit adjacent to a first louver frame unit or a second louver frame unit of a kinetic louver unit according to an embodiment of the present invention;
13 is a cross-sectional view showing a state in which a unit louver frame is inserted into a neighboring unit louver frame in a kinetic louver unit according to an embodiment of the present invention;
14 is a front view showing various kinetic motions of a kinetic louver unit according to an embodiment of the present invention;
15 is a view schematically showing a third wire winding unit in a kinetic louver unit according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in more detail with reference to the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but will be implemented in a variety of different forms, only these embodiments will complete the disclosure of the present invention, and will fully cover the scope of the invention to those skilled in the art. It is provided to inform you. Like reference numerals designate like elements in the drawings.

A kinetic louver unit, a kinetic louver module, and a kinetic louver device including the same according to a preferred embodiment of the present invention are provided on the indoor ceiling of a building to provide dynamic visual movement and color change, It is possible to provide a higher degree of freedom (DOF) movement than a kinetic device for

Hereinafter, the present invention will be described in detail with reference to examples.

1 to 3, the kinetic louver device 1000 according to the embodiment of the present invention is provided to support the kinetic louver module near the ceiling, the damper 1100, the first contact support 1110 , A kinetic louver module 1200, a second contact support part 1120, and an elevation part (not shown).

First, the dampers 1100 are capable of absorbing external vibrations, and are fixedly installed in plurality to be spaced apart from each other on a ceiling wall of a building. The damper 1100 can prevent vibrations from being transmitted to the kinetic louver module 1200 by absorbing these vibrations when vibrations occur in the pillars, ceiling, etc. of a building due to factors such as earthquakes or surrounding construction.

In an embodiment of the present invention, the damper 1100 can be applied in various ways, such as a spring structure and a hydraulic/pneumatic cylinder structure.

The first contact support portion 1110 is provided in plurality and is integrally provided below each damper 1100 . The first contact support part 1110 can partially compensate for the transmission of the vibration offset by a certain amount or more through the damper 1100 to the second contact support part 1120. For this purpose, it can be made of a vibration transmission reducing material. For example, it may be made of a plastic material.

Next, the kinetic louver module 1200 is composed of an arrangement and combination of a plurality of kinetic louver units, which will be described later, and one kinetic louver module 1200 has approximately 10 kinetic louver units arranged as shown in FIG. state can be made. Near the ceiling of the building, a plurality of such kinetic louver modules 1200 are continuously arranged to correspond to the installation area. In the following description and drawings, one kinetic louver module will be described and illustrated as an example.

As shown in FIGS. 1 and 2 , the kinetic louver module 1200 includes a module support frame 1210 and a kinetic louver unit 100 .

The module support frame 1210 is made to have a predetermined or more installation area so that a plurality of kinetic louver units 100 can be installed, and may be provided near the ceiling of a building.

As shown in FIG. 1, a plurality of kinetic louver units 100 are installed to be spaced apart from each other in the transverse direction with respect to the module support frame 1210, and each of the plurality of kinetic louver units 100 individually performs dynamic movement It is made so that it can be directed, and it can be directed to show the same movement according to the motion control. On the other hand, the plurality of kinetic louver units 100 may be individually controlled to produce a more dynamic movement by being individually controlled for directing a more dynamic movement.

In the embodiment of the present invention, the support frame 110 to be described below of the individual kinetic louver unit 100 may be connected to the lower side of the module support frame 1210, whereas the support frame 110 is omitted and the individual kinetic The lifting and lowering driver 500 of the louver unit 100 may be connected to the lower side of the module support frame 1210.

On the other hand, as described above, if the plurality of kinetic louver units 100 are made to individually produce dynamic motion, more dynamic motion can be provided, but the part to be considered in terms of stability during kinetic motion may increase. there is.

Therefore, the present invention provides an additional structure that can compensate for the decrease in stability during the kinetic motion of the kinetic louver module 1200 while providing a sufficiently high degree of freedom compared to the prior art.

Specifically, as shown in FIGS. 2 and 3 (a), the kinetic louver module 1200 according to the embodiment of the present invention is a second louver frame portion (to be described later) of each of the plurality of kinetic louver units 100 ( 300) further includes a connecting shaft 1220 connecting the hinge connection parts 400 to each other to enable simultaneous driving.

Here, the connection shaft 1220 is provided to connect each of the hinge connection parts 400 of a plurality of kinetic louver units to be described later, and the connection method and structure are not particularly limited.

Therefore, as shown in FIG. 5, the plurality of kinetic louver units 100 can be controlled to have the same movement based on one kinetic louver module 1200. In this case, each of the first elevating driving unit 510, the second elevating driving unit 520, and the third elevating driving unit 530 of the plurality of kinetic louver units 100 are all equally driven. In this case, in addition to the connecting shaft 1220, another connecting shaft (not shown) connecting the central parts of the plurality of first louver frame parts 200 and the central parts of the plurality of second louver frame parts 300 to each other is further added. can be provided.

In addition, although not specifically shown in the drawing, unlike the plurality of kinetic louver units 100, each of the first elevating driving unit 510 and the second elevating driving unit 520 to be described later are individually driven, and the connecting shaft (1220) structure is applied and all the third lifting and lowering drivers 530 are driven in the same way, so that more dynamic movements can be produced, and the latter case has a higher degree of freedom than the former case. It is desirable for motion production.

In addition, as shown in FIG. 3 (b), the connection shaft 1220 can be omitted, and the first elevating drive unit 510, the second elevating drive unit 520, and the third elevating drive unit 530 are used. When driven individually, more dynamic movements can be produced.

Next, as shown in FIGS. 1, 2 and 4, the second contact support part 1120 has a plurality of first contact support parts 1110 on the upper side of the module support frame 1210 of the kinetic louver module 1200 and It is provided in plurality so as to be coupled correspondingly.

Similarly, the second contact support part 1120 can partially compensate for the transfer of the vibration offset by a certain amount or more to the module support frame 1210 through the damper 1100 and the first contact support part 1110. To this end It may be made of a vibration transmission reducing material, for example, it may be made of a plastic material.

Next, as shown in FIG. 4, an elevating unit (not shown) is provided to elevate the module support frame 1210 between the ceiling and the floor of the building, and is fixed to the ceiling to move the module elevating wire 1130 It can be applied to a hoist or the like that can lift the module support frame 1210, that is, the kinetic louver module 1200 while winding or unwinding.

In the embodiment of the present invention, the normal kinetic motions of the first louver frame part 200 and the second louver frame part 300 of the kinetic louver unit 100 are the first contact support part 1110 and the second contact support part (1120) is made in a mutually coupled state. Therefore, as described above, when vibration is generated by an earthquake or an impact applied to a building, the damper 1100 can prevent the vibration from being transmitted to the kinetic louver module 1200.

On the other hand, when repair and inspection of the kinetic louver module 1200 is required, the lift unit (not shown) releases the module lift wire 1130 to lower the kinetic louver module 1200 to the ground in order to eliminate the risk of work at height. At this time, the coupled state between the first contact support part 1110 and the second contact support part 1120 is released. When the operator completes the inspection and repair, the lifting part (not shown) raises the kinetic louver module 1200 toward the ceiling while winding the module lifting wire 1130. At this time, the first contact support part 1110 and the second contact support part 1120 is mutually coupled state.

That is, in the embodiment of the present invention, the plurality of second contact support units 1120 are configured to be separated from or coupled to the plurality of first contact support units 1110 by driving an elevation unit (not shown).

As shown in FIG. 4, the present invention repairs and replaces parts of the kinetic louver module 1200 and the kinetic louver unit 100 by lowering the kinetic louver module 1200 to the ground by driving an elevator (not shown). If a light is required, the operator can easily work on the ground, so there is an advantage in terms of safety accident prevention and maintenance during work.

On the other hand, the kinetic louver module 1200 is lifted depending on the module lifting wire 1130, and as described above, the first contact support part ( 1110) and the second contact support portion 1120, it is required to adjust the coupling position so that they are mutually coupled.

In other words, while the kinetic louver module 1200 rises, shaking occurs in the left and right, forward and backward directions, and this shaking causes the coupling between the first contact support part 1110 and the second contact support part 1120 to be disturbed Bar, a structure for more stable and quick coupling to each other is required.

To this end, as shown in FIGS. 1, 2, and 4, the plurality of first contact support parts 1110 and the plurality of second contact support parts 1120 are coupled in place to induce in-position coupling between each other. An induction unit 1150 is provided.

Specifically, the fixed-position coupling guide 1150 includes a cone-shaped first coupling protrusion 1151 and a second coupling groove 1152, or a cone-shaped first coupling groove (not shown) and a second coupling protrusion ( not shown) may be included.

The first coupling protrusion 1151 is provided on one surface facing the second contact support portion 1120 so as to protrude toward the first contact support portion 1110 . In addition, the second coupling groove 1152 is provided in the first contact support portion 1110 so that the first coupling protrusion 1151 can be inserted.

Therefore, even if the imaginary straight line connecting the centers of the first contact support part 1110 and the second contact support part 1120 is not made in the form of a vertical line, that is, the first contact support part on a vertical line due to the shaking of the kinetic louver module 1200. Even if the center of the second coupling groove 1152 is not located on a straight line, the sharp end of the first coupling protrusion 1151 can be easily formed along the inclined surface of the second coupling groove 1152 with the pointed bottom portion of the second coupling groove 1152. can be guided. Through the structure of the conical first coupling protrusion 1151 and the second coupling groove 1152, the first contact support portion and the second contact support portion can be quickly and easily induced to be coupled in place.

On the other hand, although not specifically shown in the drawing, the position coupling induction unit 1150 is formed in the above-described structure to each other, and the conical first coupling groove (not shown) provided in the second contact support unit 1120 and A cone-shaped second coupling protrusion (not shown) provided on the first contact support portion 1110 may be included, and effects caused by this may be the same as those described above.

Hereinafter, the kinetic louver unit 100 will be described in detail.

As shown in FIG. 6, the kinetic louver unit 100 according to the embodiment of the present invention includes a support frame 110, a first louver frame part 200, a second louver frame part 300 and a lifting and lowering driving unit ( 500) are included.

The support frame 110 is installed near the ceiling so as to be supported on the ceiling of the building, and as described above, it may be fixedly installed to the module support frame 1210 through screw mounting, welding, or the like. In addition, the module support frame 1210 and the support frame 110 may be applied in substantially the same configuration, so that the elevating driving unit 500 may be directly installed on the module support frame 1210 .

The first louver frame part 200 is disposed on the lower side of the support frame 110 . The second louver frame part 300 is similarly disposed on the lower side of the support frame 110, and one end connected to the first louver frame part 200 is connected to the first louver frame part 200 so that the hinge can rotate. . That is, as shown in FIGS. 6 and 7, the hinge connection part 400 for mutual hinge rotation is provided at the connection part of the first louver frame part 200 and the second louver frame part 300. The first louver frame part 200 and the second louver frame part 300 are supported so as to be able to move up and down with respect to the support frame 110 through a lifting and lowering driving unit 500 to be described later.

As shown in FIGS. 8 and 9, the first louver frame part 200 and the second louver frame part 300 are installed in the louver frame 210 and the louver frame 210 having a certain length or more, respectively. A light emitting control unit (not shown) installed on a plurality of leds 220 and louver frame 210 and controlling the supply of power to the plurality of leds 220 and the light emitting state, coupled to the louver frame 210 to control the power of the leds 220 It includes a light diffusing unit 230 that diffuses the emitted light.

As will be described below, the first louver frame part 200 and the second louver frame part 300 each have a structure capable of adjusting the change in length, and FIGS. 8 and 9 show the first louver frame part and the second louver frame part. It is shown based on the state in which the addition is spread as a whole along the longitudinal direction.

In other words, as shown in FIG. 11 (b), the first louver frame part 200 and the second louver frame part 300 are transported to the building to be installed with their lengths reduced along the longitudinal direction In, the operator spreads the first louver frame part 200 and the second louver frame part 300 in the longitudinal direction and increases the length thereof, as shown in FIGS. 8 and 9, the above-described led 220, A light emitting control unit (not shown) and a light diffusing unit 230 are assembled and installed on site.

Specifically, as shown in FIG. 9, a support plate 240 for supporting a pcb on which an LED 220 is mounted is connected between a pair of connection brackets 255 installed adjacent to each other, which will be described later, and an upper portion thereof. The PCB on which the LED is mounted is fixedly installed, and the light diffusing unit 230 for diffusing the LED light emitted toward the ground is fixed on the upper side thereof.

Here, the light diffusion unit 230 may be installed to connect between the pair of connection brackets 255, but is not limited thereto, and any coupling method may be applied as long as it can diffuse the LED light.

In the state where the kinetic louver unit 100 according to the embodiment of the present invention is installed, the light diffusion unit 230 is preferably installed below the first louver frame unit and the second louver frame unit in the direction toward the ground, and the light diffusion The unit 230 may be made of a light diffusion sheet, acrylic, or acrylic having a plurality of intaglio/embossed patterns engraved on one side or both sides for light refraction.

In order to increase the aesthetic effect provided to people by increasing the LED light emitting area, the support plate 240, the led 220, the light diffusion unit 230, etc. are the first louver frame unit 200 and the second louver frame It is preferable that the portion 300 is installed over the entire section in the longitudinal direction in an unfolded state.

Therefore, in a state where the kinetic louver unit 100 according to the embodiment of the present invention is installed on the ceiling of a building, the first louver frame part 200 and the second louver frame part 300 do not have a structure capable of adjusting the length, remain open at all times.

In the embodiment of the present invention, as shown in FIGS. 10 to 12, the first louver frame part 200 and the second louver frame part 300 are each disposed adjacent to each other along the longitudinal direction. It includes a plurality of unit louver frame parts 250 that can be retracted or retracted in a direction to increase or decrease the overall length. That is, the louver frame 210 is made of a combination of the plurality of unit louver frame parts 250 to increase or decrease the overall length.

Here, as shown in FIGS. 10 to 12, the unit louver frame part 250 includes a pair of unit louver frames 251 and a connection bracket 255, and may be made of aluminum, which is a light weight material. Accordingly, it is possible to increase structural stability in the installed state by reducing the load transmitted to the ceiling frame.

As shown in FIG. 11, a pair of unit louver frames 251 are disposed spaced apart from each other and are provided to be drawn in or drawn out in the longitudinal direction from each other disposed adjacent to each other along the longitudinal direction, and the connection bracket 255 connects a pair of unit louver frames 251. At this time, a separate clamp 256 may be added to connect the pair of unit louver frames 251 and the connection bracket 255 to each other, and the clamp 256 may be coupled through screw fastening. When the connection bracket 255 is directly coupled to the unit louver frame 251, the clamp 256 may be omitted.

As shown in FIGS. 10 to 13, each unit louver frame 251 has an elliptical cross-sectional shape through which the inside is penetrated, and a plurality of unit louver frame parts 250 ) can minimize torsion while maintaining high strength in a state in which it is stretched in the longitudinal direction.

In an embodiment of the present invention, the plurality of unit louver frame parts 250 are made of a structure that can be drawn in or drawn out between those disposed adjacent to each other along the longitudinal direction, and the first louver frame part 200 and the second louver frame part 200 A plurality of unit louver frames 251 arranged in the longitudinal direction of the frame portion 300 are made of a structure that can be drawn in or drawn out along the longitudinal direction between adjacent ones.

Specifically, as shown in FIGS. 12 and 13, each of the plurality of unit louver frames 251 is provided with a plurality of guide grooves 252 spaced apart from each other continuously along the longitudinal direction on the outer surface, and a plurality of on the inner surface. A plurality of guide protrusions 253 are continuously provided along the longitudinal direction to correspond to the guide groove 252 of the.

Through the structure of the guide groove 252 and the guide protrusion 253, the unit louver frame 251 can be slidably inserted into another adjacent unit louver frame while maintaining the set posture, and can be easily adjusted in length while being drawn out. do.

The present invention moves the plurality of unit louver frames 251 in a direction in which they are drawn into each other adjacent to each other along the longitudinal direction, eventually reducing the overall length of the first louver frame part 200 and the second louver frame part 300, It has the advantage of being easy to store and transport. On the other hand, in a state where the first louver frame part 200 and the second louver frame part 300 are installed near the ceiling, as described above, the plurality of unit louver frames 251 have a maximum spread in the longitudinal direction, such While the expanded state is maintained, a kinetic motion is generated by driving an elevating and lowering driver to be described later.

Additionally, as shown in FIGS. 10 and 11, the unit louver frame 251 is located near the hinge connection portion 400, which is one end of each of the first louver frame portion 200 and the second louver frame portion 300 It is made so that the cross-sectional area gradually decreases from the unit louver frame located at the other end to the unit louver frame located at the other end.

That is, the plurality of unit louver frames 251 continuously connected along the longitudinal direction of the first louver frame part 200 and the second louver frame part 300 have an elliptical cross-sectional area gradually decreasing from one end to the other end made in the form

In a state where the kinetic louver unit 100 according to the embodiment of the present invention is installed on the ceiling, the shape of the first louver frame part 200 and the second louver frame part 300 is based on the hinge connection part 400, the free end ( As the cross-sectional area gradually decreases towards the outermost end), the load acting in the vertical direction due to its own weight gradually decreases toward the free end, in particular, to prevent downward deflection of the free end and weaken structural stability. can be avoided as much as possible.

Incidentally, as shown in FIG. 6, the first wire 511 and the second wire 521, which will be described later, support the central regions of the first louver frame part 200 and the second louver frame part 300. Assuming that, the section between the support point supported by the first wire and the second wire and the free ends of the first louver frame part and the second louver frame part can be applied as a kind of cantilever beam structure. Due to the nature of the cantilever beam, the deflection of the free end is inevitably greater than that of other sections. As described above, the present invention employs a structure that can gradually reduce its own weight toward the free end to reduce downward deflection of the free end. can be avoided as much as possible.

Next, as shown in FIGS. 6 and 14 , the elevating driving unit 500 moves the elevating and lowering while supporting the first and second louver frame parts 200 and 300 with respect to the support frame 110 .

Specifically, the elevating driver 500 includes a first elevating driver 510 , a second elevating driver 520 and a third elevating driver 530 .

The first lifting and lowering driving unit 510 connects between the support frame 110 and the first louver frame unit 200, and the first wire 511 connected to the first louver frame unit 200 and the first wire ( 511) is wound or unwinded and has a first wire winding unit 512 installed on the support frame 110.

Similarly, the second lifting and lowering driving unit 520 connects between the support frame 110 and the second louver frame unit 300, and the second wire 521 connected to the second louver frame unit 300 and the second It winds or unwinds the wire 521 and has a second wire winding unit 522 installed on the support frame 110 .

In addition, the third elevating and lowering driver 530 connects between the support frame 110 and the hinge connection portion of the first and second louver frame parts 200 and 300, that is, the hinge connection portion 400, to the hinge connection portion 400 It has a connected third wire 531 and a third wire winding unit 532 that winds or unwinds the third wire 531 and is installed on the support frame 110 .

Here, the first louver frame part 200 and the second louver frame part 300, each of which unit louver frame part 250 and hinge connection part 400 have a first wire 511 and a second wire 521 ) and a separate hook may be provided to connect the third wire 531.

In addition, the first to third wire winding units 512 522 532 are respectively a winch drum (not shown) capable of winding the first to third wires and a servo motor for winding or unwinding the wire by rotating the winch drum in the forward and reverse direction (not shown). city) may be included.

The first lifting and lowering driving unit 510 controls the lifting and lowering of the first louver frame unit 200, and the second lifting and lowering driving unit 520 controls the lifting and lowering of the second louver frame unit 300. The lifting and lowering driver 530 controls the lifting and lowering of the hinge connection unit 400 . Here, driving control of the first to third elevating driving units 510 , 520 , and 530 may be individually (independently) performed. That is, the rpm and forward/reverse rotation direction control of each servomotor (not shown) of the first to third wire winding units 512 , 522 , and 532 may be individually controlled, and in this case, the degree of freedom of kinetic motion of the first and second louver frame parts can be significantly increased.

In the present invention, the first louver frame part 200 and the second louver frame part 300 are mutually hinge-rotatably connected through the hinge connection part 400, and the first to third lifting and lowering driving units 510, 520, and 530 are individually lifted and lowered. Through control, various kinetic movements of the first louver frame part 200 and the second louver frame part 300 can be produced as shown in FIG. 14 .

On the other hand, as described above, the first louver frame part 200 and the second louver frame part 300 include the led 220 for emitting light of various colors to the ground, power supply for led light emission For over-emission control, it is necessary to apply power to a light emission control unit (not shown) and connect a control line.

To this end, as shown in FIGS. 6 and 14, the third lifting and lowering driver 530 supplies power to the plurality of leds 220 of the first louver frame unit 200 and the second louver frame unit 300. It further includes a power supply and communication line 538 for supplying and transmitting and receiving control signals with a light emitting control unit (not shown). That is, in the present invention, after the power supply and communication line 538 is connected to the side of the hinge connection part 400 at an approximately central position of the support frame 110, the first and second louver frame parts 200 and 300 are respectively provided with light emitting control units (not shown) applies a structure that is branched to both sides and supplied.

In this way, the structure in which the third lift driver 530 includes the power supply and communication line 538 is such that the first lift driver 510 and the second lift driver 520 each include a power supply and communication line. Compared to the structure, there is an advantage in that the cost can be reduced by relatively simplifying the structure of the first elevating drive unit 510 and the second elevating drive unit 520 and more efficiently control the LED light emission.

On the other hand, the hinge connection unit 400 can be continuously moved up and down by the driving of the third lift drive unit 530, specifically a servo motor. and the supply of the communication line 538 needs to be made. If the supply of the power supply and communication line 538 is made so as not to correspond (do not match) with the winding or unwinding operation of the third wire 531, disconnection of the power supply and communication line 538 may occur.

In order to prevent such a problem from occurring, the present invention, as shown in FIG. 15, the power supply and communication line 538 to correspond to the winding or unwinding of the third wire 531 by the third wire winding unit 532 It is made to simultaneously wind or unwind.

Specifically, as shown in FIG. 15, the third wire winding unit 532 rotates the winch drum 534 and the winch drum 534 in which the third wire 531 can be wound in a forward and reverse direction to wind the third wire. It includes a servomotor 535 that winds or unwinds. In addition to this, an auxiliary winch drum 536 is provided on the rotating shaft of the servomotor 535 to rotate at the same speed as the winch drum 534, and the power supply and communication line 538 is wound around the auxiliary winch drum 536. or unwound. Therefore, according to the normal and reverse rotation of the servo motor 535, the third wire 531 and the power supply and communication line 538 may be wound or unwound at the same speed at the same time.

In the above, the present invention has been shown and described in relation to preferred embodiments for illustrating the principles of the present invention, but the present invention is not limited to the configuration and operation as shown and described. Rather, it will be appreciated by those skilled in the art that many changes and modifications may be made to the present invention without departing from the spirit and scope of the appended claims.

100: kinetic louver unit 110: support frame
200: first louver frame part 210: louver frame
220: led 230: light diffusion unit
250: unit louver frame part 251: unit louver frame
252: guide groove 253: guide protrusion
255: connection bracket 256: clamp
300: second louver frame part 400: hinge connection part
500: elevating drive unit 510: first elevating drive unit
511: first wire 520: second lifting and lowering driving unit
521: second wire 530: third lifting and lowering driving unit
531: third wire 532: third wire winding unit
534: winch drum 535: servo motor
536: auxiliary winch drum 538: power supply and communication line
1000: kinetic louver device 1100: damper
1110: first contact support 1120: second contact support
1130: module lifting wire 1150: fixed position coupling induction unit
1151: first coupling protrusion 1152: second coupling groove
1200: kinetic louver module 1210: module support frame
1220: connecting shaft

Claims (14)

a support frame provided near the ceiling;
A first louver frame portion disposed below the support frame;
A second louver frame part disposed below the support frame and connected to the first louver frame part so that one end portion connected to the first louver frame part is hinge-rotatable; and
With respect to the support frame, the first louver frame part, the second louver frame part, and the hinge connection part of the first louver frame part and the second louver frame part are driven up and down, and individually controllable up and down drive is possible. Includes a lowering drive;
The first louver frame part and the second louver frame part are respectively disposed adjacent to each other along the longitudinal direction and connected to each other in a longitudinal direction to be retractable or retractable, and a plurality of unit louver frames capable of increasing or decreasing the overall length. including wealth,
Each of the plurality of unit louver frame parts,
A pair of unit louver frames arranged to be spaced apart from each other and provided to be drawn in or drawn out in the longitudinal direction from each other and disposed adjacent to each other along the longitudinal direction; and
A kinetic louver unit comprising a connection bracket connecting the pair of unit louver frames. According to claim 1,
The lifting and lowering drive unit,
Connecting between the support frame and the first louver frame part, winding or unwinding the first wire and the first wire connected to the first louver frame part and having a first wire winding part installed in the support frame a first lifting and lowering driving unit;
Connecting between the support frame and the second louver frame part, winding or unwinding the second wire and the second wire connected to the second louver frame part and having a second wire winding part installed in the support frame a second lifting and lowering driving unit; and
It connects between the support frame and the hinge connection part of the first and second louver frame parts, and winds or unwinds the third wire and the third wire connected to the hinge connection part of the first and second louver frame parts, A kinetic louver unit comprising a third lifting and lowering driving unit having a third wire winding unit installed on the support frame. According to claim 2,
The first louver frame part and the second louver frame part, respectively,
A louver frame having a certain length or more;
A plurality of LEDs installed on the louver frame; and
It is installed in the louver frame and includes a light emitting control unit for controlling light emission of the plurality of leds,
The third lifting and lowering driving unit,
Kinetic louver unit, characterized in that it further comprises a power supply and communication line for supplying power to the plurality of LEDs of the first louver frame part and the second louver frame part and transmitting and receiving control signals with the light emitting control unit. According to claim 3,
The third wire winding unit, characterized in that for winding or unwinding the power supply and communication line at the same time to correspond to the winding or unwinding of the third wire kinetic louver unit. According to claim 3,
The first louver frame part and the second louver frame part, respectively,
Kinetic louver unit, characterized in that it further comprises a light diffusing unit coupled to the louver frame to diffuse the light emitted by the LED. delete According to claim 1,
The unit louver frame is a kinetic louver unit, characterized in that each has an elliptical cross-sectional shape through which the inside is penetrated. According to claim 1,
Each of the unit louver frames is made of a shape with an inside penetrated, and a plurality of guide grooves spaced apart from each other are continuously provided along the longitudinal direction on the outer surface, and a plurality of guide grooves are continuously provided on the inner surface along the longitudinal direction to correspond to the plurality of guide grooves. A kinetic louver unit, characterized in that the guide projections are continuously provided. According to claim 1,
The unit louver frame,
It is made in the shape of a penetrating inside,
Characterized in that the cross-sectional area gradually decreases from the unit louver frame located near the hinge connection, which is one end of the first louver frame part and the second louver frame part, to the unit louver frame located at the other end. Kinetic louver unit . A module support frame provided near the ceiling; and
A kinetic louver module comprising a plurality of kinetic louver units of any one of claims 1 to 5 and 7 to 9 installed in a plurality spaced apart from each other in the transverse direction with respect to the module support frame. According to claim 10,
Kinetic louver module, characterized in that it further comprises a connecting shaft for connecting the hinge connection portion of each of the second louver frame portion of the plurality of kinetic louver units to each other to enable simultaneous operation. A plurality of dampers capable of absorbing external vibration by being fixed to a plurality of spaced apart from each other on the ceiling wall of the building;
a plurality of first contact support units integrally provided below each of the dampers;
A kinetic louver module according to claim 10; and
A kinetic louver device including a plurality of second contact support parts provided to be coupled with the plurality of first contact support parts on the upper side of the module support frame of the kinetic louver module. According to claim 12,
Further comprising an elevation unit capable of moving the module support frame up and down between the ceiling and the floor of the building,
The plurality of second contact support parts can be separated from or combined with the plurality of first contact support parts by driving the elevation part,
Kinetic louver device, characterized in that the plurality of first contact support portion and the plurality of second contact support portion is provided with a coupling induction portion for inducing a coupling in place with each other, respectively. According to claim 13,
The in-position coupling induction unit,
a conical first coupling protrusion or first coupling groove provided on the second contact support portion; and
A cone-shaped second coupling groove provided in the first contact support portion so that the first coupling protrusion can be inserted, or a cone-shaped second coupling groove provided in the first contact support portion so that it can be inserted into the first coupling groove A kinetic louver device comprising a protrusion.

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