KR101594842B1 - Building door with natural light and ventilation structure - Google Patents

Abstract

The present invention relates to a building door. More specifically, the present invention allows natural lighting with a simple selective control of a user while an anti-theft function where the door is closed is applied. More specifically, the present invention relates to a building door having a natural lighting and ventilation structure enabling a control over an amount of light in accordance with the need of the user, enabling ventilation as necessary in order to enable ventilation in a safety state where the door is closed, enabling the user to safely receive a package or a mail as necessary, simplifying the structure, having a stable operating structure, and enabling partial replacement in the case of a malfunction.

Description

BACKGROUND OF THE INVENTION Field of the Invention [0001] The present invention relates to a door having a natural light and a ventilation structure,

The present invention relates to a door of a building, and more particularly, to a door for a building, which enables natural light and external viewing according to the user's choice even when the door is closed, To a building door having a natural lighting and ventilation structure.

In buildings, mining generally refers to installing windows in the interior space to receive sunlight. The mining method is indirect lighting, which directly accepts sunlight through windows and indirectly accepts sunlight through reflectors.

The direct lighting system has a problem in that natural light to the indoor space is small because the incident space of the sunlight is small, and the conventional indirect lighting system has a complicated structure and a high cost.

In this way, natural light is perceived to be mined through a window, and a door of a typical building has been considered to have no relation to mining because it is not provided with means for mining. Therefore, it is impossible to think about the mining through the door, so if there is a need for mining, there is no way to open the door of the building.

However, when the temperature of the outside air such as the winter season is low, since the warmth of the room is leaked to the outside, there is a great problem in terms of heat loss to open the door for a long time.

In order to solve the above-mentioned problems, a door structure of a building capable of natural light as shown in Patent Application No. 10-0990930 has been proposed recently. When the polarizer is rotated, the degree of polarization of the polarizer , It is necessary to use a precision polarizing plate. Therefore, there is a problem that the unit price is increased, and it is difficult to set up the vertical state exactly.

In addition, the above-described structure is merely for the purpose of mining, and when the ventilation is required, the door must also be opened, thereby causing significant heat loss in winter.

Korean Patent Application Registration No. 10-0990930.

The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide a lighting device capable of natural lightening by a simple operation according to a user's selection even in a state where a door- The object of the present invention is to provide a building door having a natural lighting and ventilation structure for enabling adjustment.

It is an object of the present invention to provide a building door having a natural light and ventilation structure for enabling ventilation in a safe state in which a door is closed by making it possible to ventilate if necessary.

Further, it is an object of the present invention to provide a building door having a natural lighting and a ventilation structure for enabling reception of a package or a mail item safely as needed.

It is an object of the present invention to provide a building door having a natural lighting and a ventilation structure in order to provide a stable operating structure while being structurally simplified, and to enable partial replacement in the event of a failure.

In order to achieve the above-mentioned object, a hollow space is formed in the center of the space, and a plurality of hemispherical guide grooves are formed in the space in the left and right directions so as to oppose the upper and lower parts of the mining hole. A door formed with the continuously formed upper and lower guiders;

An opaque rod in the form of a circular rod that is formed on the upper part of the wire and sliding up and down along the guide groove to selectively open and close the mining hole; A mining unit consisting of a plurality of mining rod units formed as transparent rods in the form of circular rods which are spaced apart from each other and slid up and down along guide grooves to selectively open and close mining holes;

The upper end and the lower end of each of the siding rod units are connected to each other at the upper and lower portions of the space portion to wind and wind the wire so that the opaque rod and the transparent rod of the siding rod unit are raised and lowered to selectively open and close the mining hole; And

A power supply unit that is formed on the inner side of the door and that supplies power to operate the punching unit and a controller that is an operation unit that operates the punching unit.

As described above, the building door having the lighting and ventilation structure of the present invention has a plurality of rows of sintering rod units connected to a mining hole of a door through a transparent rod and an opaque rod, It is possible to perform natural lighting even in a state in which the security function with the door closed in the lower lift control is given, and in particular, the selection operation of the sidewall unit can be performed, and the effect of controlling the amount of light can be obtained.

Further, it is possible to obtain a ventilation effect in a safe state in which the door is closed by the selection of the wire of the mining hole as necessary.

In addition, if the need arises, the selection of the wire of the mining hole allows the door to be safely closed with the door closed, and the effect of receiving the delivery of the courier or mail can be obtained safely.

Also, by implementing a plurality of separated sintering-rod units, it is possible to achieve a simplified operation and a stable operating structure, and in particular, maintenance and repairing can be performed with ease, such as partial replacement and repair in case of failure.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is an overall perspective view of a building door having a natural light and ventilation structure of the present invention. FIG.
2 is a rear perspective view of a door of a building having a natural lighting and ventilation structure according to the present invention.
3 is a cross-sectional view of a building door having a natural lighting and ventilation structure of the present invention.
FIG. 4 is a view of a mining state of a building door having a natural lighting and ventilation structure according to the present invention. FIG.
FIG. 5 is a view showing a state where a door of a building having a natural light and ventilation structure of the present invention is closed. FIG.
6 is a view of a ventilation state of a building door having a natural lighting and ventilation structure according to the present invention.
7 is a partial view of a mining unit part of a building door having an open light and a ventilation structure according to the present invention.

The terms and words used in the present specification and claims should not be construed as limited to ordinary or dictionary terms and the inventor may appropriately define the concept of the term in order to best describe its invention It should be construed as meaning and concept consistent with the technical idea of the present invention.

Therefore, the embodiments described in the present specification and the configurations shown in the drawings are merely the most preferred embodiments of the present invention, and not all of the technical ideas of the present invention are described. Therefore, It should be understood that various equivalents and modifications may be present.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

2 is a perspective view of a door of a building having a natural lighting and ventilation structure according to the present invention, and Fig. 3 is a perspective view of a door with a natural lighting and ventilation structure according to the present invention. Fig. Sectional view of a building door.

1 to 3, a building door having a natural lighting and ventilation structure according to the present invention is composed of a door 100, a lighting unit 200, a winding means 300, and a controller 400.

Here, the door 100 has a hollow space 130 formed therein, and a square-shaped mining hole 140 passing through the front and the rear of the door 100 is formed at the center.

The upper and lower guiders 150 and 150 'are formed on the upper part and the lower part of the space part 130 so as to oppose each other on the upper and lower parts of the lighting hole 140, The guide grooves 150 and 150 'have a plurality of guide grooves 151 formed in a semicircular groove shape in the left and right direction.

The lighting unit 200 is configured to be able to control the closing and lighting state depending on whether the lighting hole 140 is open or closed. The opening and closing of the lighting hole 140 is performed by the upper and lower guiders 150 'Through a plurality of sidewall bar units 210 that slide up and down.

At this time, in each of the siding unit 210, a vertical wire 211 corresponding to each guide groove 151 is formed.

The opaque rods 212 are formed in the middle of the wire 211 in the form of a circular rod which is slid upward and downward along the guide groove 151 to selectively open and close the lighting hole 140, 212 is located in the mining hole 140, the mining hole 140 is completely closed so that the inside can not be seen through.

The opaque rod 212 is slid upward and downward along the guide groove 151 to selectively open and close the mining hole 140 so as to be spaced apart from the intermediate portion of the wire 211 to the lower portion of the opaque rod 212 A transparent bar 213 is formed in a transparent circular shape capable of penetrating the transparent hole 213. When the transparent bar 213 is positioned in the hole 140, the hole 140 is closed to provide a function of opening, So that the light can be transmitted and the light can be transmitted.

The length of the opaque rod 212, the length of the transparent rod 213 and the distance between the opaque rod 212 and the transparent rod 213 are preferably longer than the height of the mining hole 140 And the upper or lower ends of the opaque rod 212 and the transparent rod 213 are always accommodated in the guide grooves 151 of the upper and lower guiders 150 and 150 '.

The upper and lower ends of the wire 211 of each of the mining rod units 210 are connected to the upper and lower portions of the space 130 and the wire 211 is wound and unwound The opaque rods 212 and the transparent rods 213 of the mining rod unit 210 are lifted up and down so that the mining holes 140 can be selectively opened and closed.

At this time, the winding means 300 includes an upper operation portion 310 formed in the space 130 at the upper portion of the mining hole 140 to intermittently wind up and unwind the wire 211, And a lower operation part 350 formed in the space part 130 at the lower part and controlling the winding and winding of the wire 211 as opposed to the upper operation part 310.

The upper operation portion 310 includes an upper rotation shaft 311 that is installed in the space 130 in the left and right direction at the upper portion of the lighting hole 140 And upper key through holes 312 are formed on the outer circumferences of the left and right sides at the same intervals as the respective sintering rod units 210.

An upper shaft electrode plate 313 is formed on one side of the upper rotation shaft 311 so that power can be supplied to the upper shaft electrode 311. The upper shaft electrode plate 313 is provided with an upper connection terminal 313a Is protruded.

An upper driving motor 317 capable of moving in the forward and reverse directions is formed at one end of the upper rotating shaft 311 in the upper operating part 310 so as to control the rotation of the upper rotating shaft 311 in the forward and reverse directions.

An upper electrode plate 320 is formed on the upper operation portion 310. The upper electrode plate 320 is fixed to the inside of the door 100 and has a tubular shape surrounding the upper shroud electrode plate 313 And an upper contact protrusion 320a is formed on the inner circumferential surface thereof so that the upper contact protrusion 320a always contacts with the upper axis electrode plate 313 even when the upper rotation shaft 311 rotates,

The upper operating portion 310 is formed with an upper solenoid unit 330 formed inside the upper rotating shaft 311 and electrically connected to the upper connecting terminal 313a through a wire (not shown) .

The upper solenoid unit 330 includes a plurality of upper solenoid switches 331 operated by electrical signals corresponding to the upper keyhole holes 312, And an upper key 332 which is projected outward through the upper key through-hole 312 is formed.

The upper operation portion 310 is constituted by an upper wind-up roll 340 to which the upper ends of the wires 211 of the respective soda-mating unit 210 are connected to be wound and wound.

At this time, each of the upper wind-up rolls 340 surrounds the respective upper key through holes 312 of the upper rotation shaft 311, and the upper wind-up rolls 340 are installed on the upper shaft bracket 341 fixed to the inside of the door 100 Is formed through a bearing (not shown in the figure), and is configured to have no rotational interference with the upper rotary shaft 311.

An upper key groove 342 is formed on an inner circumferential surface of each of the upper winding rolls 340 so as to oppose the upper key through hole 312. When the upper soleswitch 331 of the upper soles unit 330 is operated And the upper key 332 is configured to be fitted in the upper key groove 342 through the upper key through hole 312. [

That is, the upper winding roll 340 is configured to be selectively rotatable together with the upper rotation shaft 311 depending on whether the upper key 332 of the upper solenoid switch 331 is engaged.

The lower operating portion 350 includes a lower rotating shaft 351 that is installed in the space 130 in the left and right directions at a lower portion of the mining hole 140. The lower rotating shaft 351 has a hollow And a lower key through hole 352 is formed on the outer circumferential surface at the same interval as the left and right sidewall bar units 210, respectively.

A lower shaft electrode plate 353 is formed on one side of the lower rotation shaft 351 so that power can be supplied to the lower shaft 351. A lower connection terminal 353a Is protruded.

A lower driving motor 357 capable of driving in the forward and reverse directions is formed at one end of the lower rotating shaft 351 in the lower operating part 350 so as to control rotation of the lower rotating shaft 351 in the forward and reverse directions.

The lower operation unit 350 includes a lower electrode plate 360. The lower electrode plate 360 is fixed to the inner side of the door 100 and has a tubular shape surrounding the lower axial electrode plate 353 And a lower contact protrusion 360a is formed on the inner circumferential surface thereof so that the lower contact axis electrode plate 353 always contacts with the lower rotation axis 351 even when the lower rotation axis 351 rotates.

The lower operating portion 350 is formed with a lower solenoid unit 370 formed inside the lower rotating shaft 351 and electrically connected to the lower connecting terminal 353a through a wire (not shown) .

At this time, the lower solenoid unit 370 is composed of a plurality of lower solenoid switches 371 operated by electric signals corresponding to the lower key through holes 352, And a lower key 372 which is projected outward through the lower key through hole 352 is formed.

A lower winding roll 380 is formed in the lower operation unit 350 so that the lower ends of the wires 211 of the respective soda-beam units 210 are connected to the lower winding rolls.

At this time, each of the lower wind-up rolls 380 surrounds the respective lower key through holes 352 of the lower rotation shaft 351, and has a lower bearing bracket 341 fixed to the inside of the door 100 Is formed through a bearing (not shown in the drawing), and is configured to have no rotational interference with the lower rotation shaft 351.

A lower key groove 382 is formed on an inner circumferential surface of each of the lower winding rolls 380 to oppose the lower key through hole 352. When the lower soleswitch 371 of the lower soles unit 370 is operated And the lower key 372 is configured to be inserted into the lower key groove 382 through the lower key through hole 352.

That is, the lower winding roll 380 is configured to be selectively rotatable together with the lower rotary shaft 351 according to whether the lower key 372 of any one lower solenoid switch 371 is engaged.

The upper drive motor 317 and the lower drive motor 357 of the upper and lower operation parts 310 and 350 have the same rotational force and are configured to impart rotational forces in opposite directions to each other. The lower winding roll 380 is driven by the lower driving motor 357 when the upper end of the wire 211 is wound on the upper winding roll 340 by the driving of the upper driving motor 317, When the winding force of the wire 211 is given to the upper wind-up roll 340, the lower end of the lower wind-up roll 340 is rotated in the opposite direction to that of the upper wind- The wind-up force of the wire 211 is given to the winding roll 380, and the sintering rod unit 210 is lowered.

The controller 400 is formed to be exposed to the inside of the door 100.

At this time, the controller 400 firstly includes a power supply unit 410 to which a normal battery is mounted so as to be able to supply power for operating the power up unit 300, The upper drive motor 317 and the upper electrode plate 320 of the operation unit 310 and the lower drive motor 357 and the lower electrode plate 360 of the lower operation unit 350 and the wires So that the power can be supplied.

The controller 400 is provided with an operating portion 420 for operating the operation of the driving means 300. The operating portion 420 is operated by the upper driving motor 317 of the upper operating portion 310, Unit 330 and the lower driving motor 357 and the lower solenoid unit 370 of the lower operating portion 350. [

The upper and lower solenoid switches 331 and 371 constituting the upper and lower solenoid units 330 and 370 are operated individually or individually in the operating unit 420. At the same time, The clockwise direction of the upper drive motor 317 is shifted from the upper winding roll 340 to the upper side of the sphere unit 210 when the upper rotation shaft 311 is rotated. The wire 211 is wound and the sintering rod unit 210 is lifted while the upper rotation shaft 311 is rotated in the opposite direction (counterclockwise) to the upper winding roll 340, It is natural that the lower shaft driving unit 357 operates in the direction opposite to the upper driving motor 317 to rotate the lower rotating shaft 351. In this case,

Hereinafter, the operation of the building door having the natural lighting and ventilation structure according to the present invention will be described in detail with reference to the accompanying drawings.

According to the present invention, a building door having a natural lighting and ventilation structure can close and light and vent the mining hole 140 according to the position of the mining unit 200 as needed.

First, referring to FIGS. 1 to 3, as shown in FIG. 4,

This is possible by closing the mining hole 140 by using the transparent rod 213 formed in the intermediate upper portion of the wire 211.

In detail, the transparent rod 213 is positioned at the middle lower portion of the wire 211, and the transparent rod 213 is raised to close the light hole 140, The upper driving motor 317 transmits a rotational force in the winding direction of the upper wind-up roll 340 when the siding bar unit 210 is raised in the operating unit 420. At this time, All of the upper solenoid switches 331 of the upper solenoid unit 330 formed in the upper rotary shaft 311 are operated and the upper key 332 is pulled out and pulled out, 332 are coupled to the upper key groove 342 of the upper wind-up roll 340 through the upper key through-hole 312 so that rotational force is transmitted to the upper wind-up roll 340.

The upper winding roll 340 causes the wire 211 to be wound and the sintering rod unit 210 is raised so that the transparent bar 213 is positioned in the mining hole 140 and the mining hole 140 is closed .

That is, when the transparent bar 213 closes the mining hole 140 as described above, the transparent bar 213 can transmit light and can be mined. At the same time, .

Referring to FIGS. 1 to 3, as shown in FIG. 5,

This is possible by closing the mining hole 140 by using the opaque rod 212 formed in the intermediate upper portion of the wire 211.

In detail, the opaque rod 212 is located at the middle upper portion of the wire 211, the opaque rod 212 is lowered to close the hole 140, The upper driving motor 317 transmits a rotational force in the winding direction of the upper wind-up roll 340. In this case, when the operation unit 420 is operated to descend the siding bar unit 210, All of the upper solenoid switches 331 of the upper solenoid unit 330 formed in the upper rotary shaft 311 are operated and the upper key 332 is pulled out and pulled out, 332 are coupled to the upper key groove 342 of the upper wind-up roll 340 through the upper key through-hole 312 so that rotational force is transmitted to the upper wind-up roll 340.

Thus, the upper winding roll 340 winds the wire 211, so that the moonlight bar unit 210 rises and the opaque rod 212 is positioned in the mining hole 140 to close the mining hole 140 .

That is, when the opaque rod 212 closes the mining hole 140 as described above, the light can not be transmitted. Therefore, the mining effect can not be expected and the crime prevention function can be given.

Although the upper and lower lifting and lowering states of the siding pole unit 210 by winding and winding the upper wind-up roll 340 according to the operation of the upper drive motor 317 have been described above, The rotation of the lower rotation shaft 351 and the rotation of the lower solenoid unit 370 cause the rotational force to be transmitted to the lower winding roll 380, Roll 340 < RTI ID = 0.0 > 340 '. ≪ / RTI >

Referring to FIGS. 1 to 3, as shown in FIG. 6,

This is possible by selecting the forward driving motor 317 and the bottom driving motor 357 in the forward and reverse directions while the wire 211 formed between the opaque rod 212 and the transparent rod 213 is rotated And a space is formed between the wires 211 so that air can be ventilated and a small package such as a courier or mail can be received through the gap.

That is, if the opaque rods 212 are closed by the opaque rods 212, the rods 211 may be positioned in the mining holes 140 by raising the mining rod unit 210, When the mining hole 140 is closed by the mining rod unit 213, the mining rod unit 210 is lowered so that the wire 211 is positioned in the mining hole 140. The elevating operation can be performed according to the state of light by the transparent bar 213 or the state of blocking the light by the opaque rod 212, and a detailed description thereof will be omitted.

1 to 3, the operation unit 420 of the controller 400 may be configured as shown in FIG. 7, for example, as shown in FIG. 7, When the upper and lower solenoid switches 331 and 371 constituting the upper and lower solenoid units 330 and 370 are selectively operated, only the operation of the selected fleet rod unit 210 becomes possible, Allowing for mining.

As described above, the building door having the natural lighting and ventilation structure of the present invention can selectively block mining and ventilation while maintaining the security function according to the demand of the user even when the door is closed, It becomes very convenient, and in particular, it is very convenient to carry out the maintenance in accordance with the replacement in the case of a partial failure through each of the separate flare unit.

100: door 130:
140: mining hole 150, 150 ': upper and lower guider
151: guide groove
200: mining unit 210: mining rod unit
211: wire 212: opaque rod
213: transparent rod
300: recommending means 310: upper operating portion
311: upper rotation shaft 312: upper key penetration hole
313 Upper shaft electrode plate 313a: Upper connection terminal
317: upper drive motor
320: upper electrode plate 320a: upper contact projection
330: Upper sole unit 331: Upper sole switch
332: upper key 340: upper winding roll
341: upper bearing bracket 342: upper key groove
350: lower operating portion 351: lower rotating shaft
352: Lower key penetration hole 353: Lower shaft electrode plate
353a: Lower connection terminal 357: Lower drive motor
360: lower electrode plate 360a: lower contact projection
370: Lower solenoid unit 371: Lower solo switch
372: Lower key 380: Lower winding roll
381: Lower bearing bracket 382: Lower key groove
400: controller 410: power supply
420:

Claims (2)

A plurality of rectangular holes 140 are formed in the center of the space 130 so as to oppose the upper and lower portions of the hole 140 in the space 130, A door 100 having upper and lower guiders 150 and 150 'formed with a continuous hemispherical guide groove 151;
A vertical wire 211 arranged in each guide groove 151 and an upper portion formed at an intermediate portion of the wire 211 and slid up and down along the guide groove 151 to selectively open and close the mining hole 140 The opaque rods 212 are separated from the opaque rods 212 at the middle portion of the wire 211 and are slid up and down along the guide grooves 151 to select the mining holes 140 A mining unit 200 made up of a plurality of mining rod units 210 made of transparent rods 213 in the form of circular rods for opening and closing;
The upper and lower ends of the wire 211 of each of the sidewinding bar units 210 are connected to each other at the upper portion and the lower portion of the space portion 130 to wind and inscribe the wire 211 to separate the opaque rod 212 of the sidewall bar unit 210 and the transparent A recommending means (300) for interrupting the rod (213) upwardly and downwardly to selectively open and close the mining hole (140); And
A power supply unit 410 which is formed on an inner side of the door 100 and supplies power for operating the power supply unit 300 and a controller 400 comprising an operation unit 420 for operating the operation of the power supply unit 300 The door of a building having a natural light and ventilation structure.
The method according to claim 1,
The recommending means (300)
An upper operation part 310 formed in the space 130 at the upper part of the mining hole 140 and connected to an upper end of the wire 211 of each of the mining rod units 210 to intercept the winding and winding of the wire 211, A lower operating part 310 formed in the space 130 at the lower part of the mining hole 140 and connected to the lower end of the wire 211 of the siding unit 210 to be rotated with the upper operating part 310, (350)
The upper operation part 310 is formed in the space 130 and has an upper key through hole 312 formed at the same interval as the left and right sidewall bar units 210 on the outer circumferential surface, An upper hollow upper rotating shaft 311 formed with an upper shaft electrode plate 313 having a connecting terminal 313a, an upper upper driving motor 317 formed at one side of the upper rotating shaft 311 and transmitting a forward and reverse rotational force, An upper electrode plate 320 which is fixed to the inside of the door 100 and surrounds the upper shaft electrode plate 313 and has an upper contact protrusion 320a formed on the inner circumferential surface thereof so as to have constant contact force with the upper shaft electrode plate 313, A plurality of electric signal type upper solenoid switches 331 which are formed inside the upper rotary shaft 311 and are energized with the upper connection terminals 313a so as to interrupt the appearance of the upper key 332 by the upper key through holes 312 An upper solenoid unit 330 fixed to the inside of the door 100, The upper key groove 342 is formed on the inner circumferential surface and the upper end of each wire 211 is connected to the outer circumference of the upper key groove 342 without being interfered with the rotation of the upper rotation shaft 311 through the racket 341 Up rewinding roll 340,
The lower operating portion 350 is formed in the space 130 and has a lower key through hole 352 formed at the same interval as the left and right sidewall bar units 210 on the outer circumferential surface thereof, An inner hollow lower rotating shaft 351 formed with a lower shaft electrode plate 353 having a connecting terminal 353a, a lower driving motor 357 formed at one side of the lower rotating shaft 351 for transmitting a forward and reverse rotational force, A lower electrode plate 360 which is fixed on the inner side of the lower shaft electrode plate 353 and surrounds the lower shaft electrode plate 353 and has a lower contact protrusion 360a formed on the inner circumferential surface thereof so as to have constant contact force with the lower axis electrode plate 353, A plurality of electric signal type lower solenoid switches 371 which are formed inside the lower rotary shaft 351 and are energized with the lower connection terminals 353a to intercept the lower key 372 from the lower key through holes 352, A lower solenoid unit 370, and a lower shaft bracket 370 fixed to the inside of the door 100, A lower key groove 382 is formed on the inner circumferential surface and a lower end of each wire 211 is connected to the outer circumference of the lower key hole 382 through rotation of the lower rotation shaft 351 through a rotation shaft 381, And a lower winding roll 380,
Wherein the upper drive motor (317) and the lower drive motor (357) have the same rotational force and operate in the forward and reverse directions, and rotate in opposite directions to each other.

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