KR101568029B1 - Apparatus for opening/closing door - Google Patents

Abstract

The present invention explains a device for opening or closing a building window. The device for opening or closing a building window comprises: a sliding rail unit (100) installed to be elevated in upper and lower ends of a square installation hole (11) formed on a wall (10) which forms an inner space (10a); a window unit (200) arranged in the installation hole (11) and coupled to the sliding rail unit (100) by sliding to be opened or closed by sliding; and an opening or closing unit (300) for disconnecting a sliding connection state between the window unit and the sliding rail unit and repetitively rotating the window unit according to a temperature of the inner space to ventilate the inner space.

Description

{APPARATUS FOR OPENING / CLOSING DOOR}

The present invention relates to a window opening / closing apparatus for a building, and more particularly, to a window opening / closing apparatus for a building, and more particularly to a window opening / closing apparatus for a building, which is capable of operating the air conditioner in a state in which the sliding window is rotated and rotated repeatedly, The present invention relates to a construction window opening / closing apparatus.

In general, the system window device is widely used in a high-rise office, an apartment, and the like, and has a hermetic structure capable of maintaining a hermeticity of a certain level or more to the necessary wind pressure. This is accomplished by a strong fastening of window frames and windows, which can eliminate problems such as window sway, wind noise, and external noise.

However, when the cooling system is operated for cooling in a room enclosed by a window, there is a problem that energy to be supplied to cool the room that is raised to a high temperature to the set cooling temperature is wasted.

In addition, the conventional window is composed of a simple sliding door or a casement, and performs only a simple opening or closing and soundproof function, so that there is no function required for indoor cooling substantially.

For this purpose, conventionally, a method of tinting windows is used, but this is limited in cooling and ventilation.

A prior art document related to the present invention is Korean Patent Laid-Open Publication No. 10-2005-0039030 (Apr. 29, 2005).

SUMMARY OF THE INVENTION An object of the present invention is to provide a window opening and closing apparatus for a building which can operate an air conditioner in a state in which a sliding window is rotated and rotated repeatedly based on room temperature to introduce outdoor air into the window .

In a preferred aspect, the present invention describes a window opening and closing apparatus for a building.

The building window opening and closing apparatus comprises a sliding rail part 100 installed to be able to move up and down from a top and a bottom of a rectangular installation hole 11 formed in a wall 10 constituting an interior space 10a; A window unit 200 disposed in the installation hole 11 and slidingly coupled to the sliding rail 100 to be opened and closed; And an opening / closing part 300 for releasing the sliding engagement of the window part with the sliding rail according to the temperature of the indoor space, and repeatedly rotating the window part to ventilate the indoor space.

The indoor space (10a) is provided with a cooling system (400) for introducing outdoor air into the outdoor space, for exchanging heat with a predetermined cooling temperature and supplying outdoor air heat-exchanged to the indoor space.

The opening and closing unit 300 drives the cooling facility 400 when the temperature of the indoor space 10a reaches a preset reference temperature.

The sliding rail part 100 includes a first sliding rail part 110 installed at an upper end of the installation hole 11 and a second sliding rail part 120 installed at a lower end of the installation hole 11 Respectively.

The first sliding rail 110 may include a first sliding rail 111 which is disposed at an upper end of the installation hole 11 and is slidably engaged with an upper end of the window unit 200, And a first elevator 112 for moving the sliding rail 111 up and down.

The second sliding rail part 120 includes a second sliding rail 121 which is disposed at a lower end of the installation hole 11 and is slidably engaged with a lower end of the window part 200, And a second elevator 122 for raising and lowering the sliding rail 121.

The window unit 200 includes a first window 210 and a second window 220 that are disposed to overlap with each other and are slidably opened and closed.

An upper first coupling groove 211 is formed at an upper center of the first window 210. A lower first coupling groove 212 is formed at a lower center of the first window 210, An upper second coupling groove 221 is formed at an upper center of the second window 220 and a lower second coupling groove 222 is formed at a lower center of the second window 220.

An upper third coupling groove 231 is formed at an upper boundary between the first window 210 and the second window 220 and a lower boundary between the first window 210 and the second window 220 The lower third coupling groove 232 is formed.

The first sliding rail 111 is provided with an upper side first engaging groove 211, an upper side second engaging groove 221 and upper and lower side engaging grooves 231, , And three rotation guide holes (111a, 111b, 111c) are formed.

The second sliding rail 121 is provided with a lower side first engaging groove 221, a lower side second engaging groove 222, and a lower side engaging the lower third engaging groove 223 And three rotation guide holes 121a, 121b and 121c are formed.

The opening and closing part 300 includes a first rotating part 310, a second rotating part 320, a third rotating part 330, a temperature sensor 340, a controller 350, and a mode selector 360 Respectively.

The first rotating part 310 includes an upper first rotating member 311 that is elevatably positioned in the upper first rotation guide hole 111a and is engaged with the upper first coupling groove 211 when it is lowered, And an upper first elevator 312 for elevating and lowering the upper first rotatable member 311. The lower first rotatable guide hole 121b is positioned so as to be able to ascend and descend, And a lower first elevator 314 for moving the lower first rotating member 313 upward and downward.

The second rotating portion 320 includes an upper second rotating member 321 that is movable up and down in the upper second rotation guide hole 111b and is fitted into the upper second coupling groove 221 when the lower portion is lowered, And an upper second elevator 322 for elevating and lowering the upper second rotary member 321. The upper second rotary member 321 is positioned so as to be able to move up and down in the lower second rotation guide hole 121b, And a lower second elevator 324 for moving the lower second rotary member 323 upward and downward.

The third rotating part 330 includes an upper third rotating member 331 that is elevatably positioned in the upper third rotation guide hole 111c and is engaged with the upper third coupling groove 231 when the lower part is lowered, And an upper third elevator 332 for elevating and lowering the upper third rotary member 331. The upper third rotary member 331 is positioned so as to be able to ascend and descend in the lower third rotation guide hole 121c, A lower third rotating member 333 fitted and coupled to the groove 232 and a lower third elevator 334 for moving the lower third rotating member 333 upward and downward.

The temperature sensor 340 measures the temperature of the indoor space 10a and transmits the measured temperature to the controller 350. [

The mode selector 360 selects a normal operation mode and transmits a corresponding selection signal to the controller.

The controller 350 drives the upper first elevator 312 and the lower first elevator 314 to move the upper first rotatable member 311 and the lower first rotatable member 314 to each other, The first rotation shaft C1 is formed by coupling the first rotary member 313 to the upper first coupling groove 211 and the lower first coupling groove 212 of the first window 210, The upper second rotating member 321 and the lower second rotating member 323 are driven by the second elevator 322 and the lower second elevator 324 so that the upper side rotator 321, The second rotary shaft C2 is coupled to the second coupling groove 221 and the lower second coupling groove 222 to drive the upper third elevator 332 and the lower third elevator 334, The upper third rotating member 331 and the lower third rotating member 333 are coupled to the upper third coupling groove 231 and the lower third coupling groove 232 of the first and second windows 210 and 220, So as to form the third rotation axis C3.

The first and second sliding rails 111 and 121 are raised and lowered from the upper and lower ends of the window unit 200 using the first and second elevators 112 and 122.

The first window 210 is rotated by using the first rotator 510 so that the measured temperature reaches a preset reference temperature or the second window 220 is rotated using the second rotator 520 Or reciprocally rotates the first and second windows 210 and 220 using the first rotator 530.

The mode selector 360 selects a facility operation mode and transmits a corresponding selection signal to the controller 350.

The controller 350 uses the window unit 200 to seal the installation hole 11 and drives the cooling facility 400 after the normal operation mode is started.

The upper first rotating member 311 and the lower first rotating member 313 and the upper second rotating member 321 and the lower second rotating member 323 and the upper third rotating member 331 And the lower third rotary member 333 are formed of metal.

The inner periphery of the upper first coupling groove 211 and the lower first coupling groove 212 and the inner periphery of the upper second coupling groove 221 and the lower second coupling groove 222, An electromagnet 610 which is magnetized according to whether a current is supplied from the current supplier 600 electrically connected to the controller 350 is installed in each of the inner circumference of the coupling groove 231 and the lower third coupling groove 232 do.

Each of the electromagnets 610 fixes the metal by a magnetic force in the case of a magnetic field.

In addition, the refrigerant circulation pipe circulating inside the first sliding rail and the second sliding rail receives the refrigerant having the predetermined cooling temperature from outside.

Each of the first and second windows is formed as a double glass window to form an internal space.

The internal space of the double glass window is filled with water. In the internal space, a plurality of reflectors arranged to be inclined upward toward the outdoor side are formed at intervals along the upper and lower sides, and the water receives a control signal from the controller Exposed to the cooling coil to be cooled and cooled to a constant temperature.

The present invention has an effect that the air conditioner can be operated in a state in which the room temperature is lowered by introducing the outside air by repeatedly rotating the sliding window by rotating the window by changing the indoor temperature.

1 is a view showing a construction window opening / closing apparatus of the present invention.
FIG. 2 is a view showing a state in which a first window is ready to be rotated in a construction window opening / closing apparatus of the present invention.
3 is a conceptual diagram showing a state in which the first window is rotated.
4 is a conceptual diagram showing a state in which the second window is rotated.
5 is a conceptual diagram showing a state in which the first and second windows are rotated together.
Fig. 6 is a conceptual diagram showing the operation of a window opening and closing apparatus for a building according to the present invention.

Hereinafter, a construction window opening / closing apparatus of the present invention will be described with reference to the accompanying drawings.

FIG. 1 is a view showing a construction window opening / closing apparatus of the present invention, FIG. 2 is a view showing a state in which a first window is ready for rotation operation in a construction window opening and closing apparatus of the present invention, FIG. 4 is a conceptual view showing a state in which the second window is rotated, FIG. 5 is a conceptual view showing a state in which the first and second windows are rotated together, FIG. 6 is a conceptual view showing the operation of the window opening / Fig.

1 to 6, a construction window opening / closing apparatus according to the present invention includes a sliding door (not shown) installed at an upper end and a lower end of a rectangular installation hole 11 formed in a wall 10 constituting an interior space 10a, A rail part (100); A window unit 200 disposed in the installation hole 11 and slidingly coupled to the sliding rail 100 to be opened and closed; And an opening / closing part 300 for releasing the sliding engagement of the window part with the sliding rail according to the temperature of the indoor space, and repeatedly rotating the window part to ventilate the indoor space.

The indoor space (10a) is provided with a cooling system (400) for introducing outdoor air into the outdoor space, for exchanging heat with a predetermined cooling temperature and supplying outdoor air heat-exchanged to the indoor space.

The opening and closing unit 300 drives the cooling facility 400 when the temperature of the indoor space 10a reaches a preset reference temperature.

The sliding rail part 100 includes a first sliding rail part 110 installed at an upper end of the installation hole 11 and a second sliding rail part 120 installed at a lower end of the installation hole 11 Respectively.

The first sliding rail 110 may include a first sliding rail 111 which is disposed at an upper end of the installation hole 11 and is slidably engaged with an upper end of the window unit 200, And a first elevator 112 for moving the sliding rail 111 up and down.

The second sliding rail part 120 includes a second sliding rail 121 which is disposed at a lower end of the installation hole 11 and is slidably engaged with a lower end of the window part 200, And a second elevator 122 for raising and lowering the sliding rail 121.

The window unit 200 includes a first window 210 and a second window 220 that are disposed to overlap with each other and are slidably opened and closed.

An upper first coupling groove 211 is formed at an upper center of the first window 210. A lower first coupling groove 212 is formed at a lower center of the first window 210, An upper second coupling groove 221 is formed at an upper center of the second window 220 and a lower second coupling groove 222 is formed at a lower center of the second window 220.

An upper third coupling groove 231 is formed at an upper boundary between the first window 210 and the second window 220 and a lower boundary between the first window 210 and the second window 220 The lower third coupling groove 232 is formed.

The first sliding rail 111 is provided with an upper side first engaging groove 211, an upper side second engaging groove 221 and upper and lower side engaging grooves 231, , And three rotation guide holes (111a, 111b, 111c) are formed.

The second sliding rail 121 is provided with a lower side first engaging groove 221, a lower side second engaging groove 222, and a lower side engaging the lower third engaging groove 223 And three rotation guide holes 121a, 121b and 121c are formed.

The opening and closing part 300 includes a first rotating part 310, a second rotating part 320, a third rotating part 330, a temperature sensor 340, a controller 350, and a mode selector 360 Respectively.

The first rotating part 310 includes an upper first rotating member 311 that is elevatably positioned in the upper first rotation guide hole 111a and is engaged with the upper first coupling groove 211 when it is lowered, And an upper first elevator 312 for elevating and lowering the upper first rotatable member 311. The lower first rotatable guide hole 121b is positioned so as to be able to ascend and descend, And a lower first elevator 314 for moving the lower first rotating member 313 upward and downward.

The second rotating portion 320 includes an upper second rotating member 321 that is movable up and down in the upper second rotation guide hole 111b and is fitted into the upper second coupling groove 221 when the lower portion is lowered, And an upper second elevator 322 for elevating and lowering the upper second rotary member 321. The upper second rotary member 321 is positioned so as to be able to move up and down in the lower second rotation guide hole 121b, And a lower second elevator 324 for moving the lower second rotary member 323 upward and downward.

The third rotating part 330 includes an upper third rotating member 331 that is elevatably positioned in the upper third rotation guide hole 111c and is engaged with the upper third coupling groove 231 when the lower part is lowered, And an upper third elevator 332 for elevating and lowering the upper third rotary member 331. The upper third rotary member 331 is positioned so as to be able to ascend and descend in the lower third rotation guide hole 121c, A lower third rotating member 333 fitted and coupled to the groove 232 and a lower third elevator 334 for moving the lower third rotating member 333 upward and downward.

The temperature sensor 340 measures the temperature of the indoor space 10a and transmits the measured temperature to the controller 350. [

The mode selector 360 selects a normal operation mode and transmits a corresponding selection signal to the controller.

The controller 350 drives the upper first elevator 312 and the lower first elevator 314 to move the upper first rotatable member 311 and the lower first rotatable member 314 to each other, The first rotation shaft C1 is formed by coupling the first rotary member 313 to the upper first coupling groove 211 and the lower first coupling groove 212 of the first window 210, The upper second rotating member 321 and the lower second rotating member 323 are driven by the second elevator 322 and the lower second elevator 324 so that the upper side rotator 321, The second rotary shaft C2 is coupled to the second coupling groove 221 and the lower second coupling groove 222 to drive the upper third elevator 332 and the lower third elevator 334, The upper third rotating member 331 and the lower third rotating member 333 are coupled to the upper third coupling groove 231 and the lower third coupling groove 232 of the first and second windows 210 and 220, So as to form the third rotation axis C3.

The first and second sliding rails 111 and 121 are raised and lowered from the upper and lower ends of the window unit 200 using the first and second elevators 112 and 122.

The first window 210 is rotated by using the first rotator 510 so that the measured temperature reaches a preset reference temperature or the second window 220 is rotated using the second rotator 520 Or reciprocally rotates the first and second windows 210 and 220 using the first rotator 530.

The mode selector 360 selects a facility operation mode and transmits a corresponding selection signal to the controller 350.

The controller 350 uses the window unit 200 to seal the installation hole 11 and drives the cooling facility 400 after the normal operation mode is started.

The upper first rotating member 311 and the lower first rotating member 313 and the upper second rotating member 321 and the lower second rotating member 323 and the upper third rotating member 331 And the lower third rotary member 333 are formed of metal.

The inner periphery of the upper first coupling groove 211 and the lower first coupling groove 212 and the inner periphery of the upper second coupling groove 221 and the lower second coupling groove 222, An electromagnet 610 which is magnetized according to whether a current is supplied from the current supplier 600 electrically connected to the controller 350 is installed in each of the inner circumference of the coupling groove 231 and the lower third coupling groove 232 do.

Each of the electromagnets 610 fixes the metal by a magnetic force in the case of a magnetic field.

In addition, the refrigerant circulation pipe circulating inside the first sliding rail and the second sliding rail receives the refrigerant having the predetermined cooling temperature from outside.

Although not shown in the drawing, each of the first and second windows is formed as a double glass window to form an internal space.

The internal space of the double glass window is filled with water. In the internal space, a plurality of reflectors arranged to be inclined upward toward the outdoor side are formed at intervals along the upper and lower sides, and the water receives a control signal from the controller Exposed to the cooling coil to be cooled and cooled to a constant temperature.

According to the present invention, it is possible to operate the air conditioner in a state in which the indoor temperature is lowered by introducing the outside air by repeatedly rotating the sliding window by rotating the window by rotating the indoor window.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it will be understood by those skilled in the art that various changes and modifications may be made without departing from the scope of the present invention.

Therefore, the scope of the present invention should not be limited to the above-described embodiments, but should be determined by the scope of the appended claims and equivalents thereof.

It is to be understood that the foregoing embodiments are illustrative and not restrictive in all respects and that the scope of the present invention is indicated by the appended claims rather than the foregoing description, It is intended that all changes and modifications derived from the equivalent concept be included within the scope of the present invention.

100: Sliding rail part
200:
300:
400: Air-conditioning system

Claims (5)

A sliding rail part 100 installed to be able to move up and down from an upper end and a lower end of a rectangular installation hole 11 formed in a wall 10 constituting an indoor space 10a;
A window unit 200 disposed in the installation hole 11 and slidingly coupled to the sliding rail 100 to be opened and closed; And
And an opening / closing part (300) for releasing the sliding engagement of the window part with the sliding rail according to the temperature of the indoor space, and repeatedly rotating the window part to ventilate the indoor space,
The indoor space 10a is provided with a cooling system 400 for supplying outdoor air to the indoor space by exchanging heat with outdoor air to a predetermined cooling temperature,
Wherein the opening / closing part (300) drives the cooling device (400) when the temperature of the indoor space (10a) reaches a preset reference temperature.
The method according to claim 1,
The sliding rail part (100)
A first sliding rail part 110 installed at an upper end of the installation hole 11,
And a second sliding rail part (120) installed at a lower end of the installation hole (11)
The first sliding rail 110 may include a first sliding rail 111 which is disposed at an upper end of the installation hole 11 and is slidably engaged with an upper end of the window unit 200, And a first elevator 112 for raising and lowering the sliding rail 111,
The second sliding rail part 120 includes a second sliding rail 121 which is disposed at a lower end of the installation hole 11 and is slidably engaged with a lower end of the window part 200, And a second elevator (122) for raising and lowering the sliding rail (121).
3. The method of claim 2,
The window unit (200)
A first window 210 and a second window 220 which are disposed to overlap with each other and are slidably opened and closed,
An upper first coupling groove 211 is formed at an upper center of the first window 210,
A lower first coupling groove 212 is formed at the lower center of the first window 210,
An upper second coupling groove 221 is formed at an upper center of the second window 220,
A lower second coupling groove 222 is formed at the lower center of the second window 220,
An upper third coupling groove 231 is formed at an upper boundary between the first window 210 and the second window 220,
A lower third coupling groove 232 is formed at a lower boundary between the first window 210 and the second window 220,
The first sliding rail 111 is provided with an upper side first engaging groove 211, an upper side second engaging groove 221 and upper and lower side engaging grooves 231, , Three rotation guide holes (111a, 111b, 111c) are formed,
The second sliding rail 121 is provided with a lower side first engaging groove 221, a lower side second engaging groove 222, and a lower side engaging the lower third engaging groove 223 , Three rotation guide holes (121a, 121b, 121c) are formed,
The opening / closing part 300,
A temperature sensor 340, a controller 350 and a mode selector 360. The first rotation unit 310, the second rotation unit 320, the third rotation unit 330, the temperature sensor 340,
The first rotating part 310 includes an upper first rotating member 311 that is elevatably positioned in the upper first rotation guide hole 111a and is engaged with the upper first coupling groove 211 when it is lowered, And an upper first elevator 312 for elevating and lowering the upper first rotatable member 311. The lower first rotatable guide hole 121b is positioned so as to be able to ascend and descend, A lower first rotating member 313 fitted and coupled to the groove 212 and a lower first elevator 314 for moving the lower first rotating member 313 up and down,
The second rotating portion 320 includes an upper second rotating member 321 that is movable up and down in the upper second rotation guide hole 111b and is fitted into the upper second coupling groove 221 when the lower portion is lowered, And an upper second elevator 322 for elevating and lowering the upper second rotary member 321. The upper second rotary member 321 is positioned so as to be able to move up and down in the lower second rotation guide hole 121b, A lower second rotating member 323 which is engaged with the groove 222 and a lower second elevator 324 which moves the lower second rotating member 323 up and down,
The third rotating part 330 includes an upper third rotating member 331 that is elevatably positioned in the upper third rotation guide hole 111c and is engaged with the upper third coupling groove 231 when the lower part is lowered, And an upper third elevator 332 for elevating and lowering the upper third rotary member 331. The upper third rotary member 331 is positioned so as to be able to ascend and descend in the lower third rotation guide hole 121c, A lower third rotating member 333 fitted and coupled to the groove 232 and a lower third elevator 334 for moving the lower third rotating member 333 up and down,
The temperature sensor 340 measures the temperature of the indoor space 10a, transmits the measured temperature to the controller 350,
The mode selector 360 selects a normal operation mode and transmits a corresponding selection signal to the controller,
The controller (350)
The upper first elevator 312 and the lower first elevator 314 are driven to rotate the upper first rotating member 311 and the lower first rotating member 313, Is coupled to the upper first coupling groove 211 and the lower first coupling groove 212 of the first window 210 to form a first rotary shaft,
The upper second rotator 322 and the lower second elevator 324 are driven so that the upper second rotatable member 321 and the lower second rotatable member 323 are rotated in the same direction as that of the second window 220, A second rotation shaft may be formed by engaging with the upper second engagement groove 221 and the lower second engagement groove 222,
The upper third elevator 332 and the lower third elevator 334 are driven so that the upper third rotating member 331 and the lower third rotating member 333 are moved to the first and second windows 210 and 220, The upper third coupling groove 231 and the lower side third coupling groove 232 of the first rotary shaft 231 form a third rotary shaft,
Using the first and second elevators 112 and 122, the first and second sliding rails 111 and 121 are raised and lowered from the upper and lower ends of the window unit 200,
So that the measured temperature reaches a preset reference temperature
The first rotator 510 is used to reciprocally rotate the first window 210,
The second rotator 520 may be used to reciprocally rotate the second window 220,
Wherein the first and second windows (210, 220) are reciprocally rotated using the first rotator (530).
Claim 4 has been abandoned due to the setting registration fee. The method of claim 3,
The mode selector 360 selects a facility operation mode and transmits a corresponding selection signal to the controller 350,
The controller (350)
Closing the installation hole (11) by using the window part (200) after driving the general operation mode, and driving the cooling facility (400).
Claim 5 has been abandoned due to the setting registration fee. The method of claim 3,
The upper first rotating member 311 and the lower first rotating member 313,
The upper second rotating member 321 and the lower second rotating member 323,
The upper third rotating member 331 and the lower third rotating member 333 are made of metal,
The inner circumference of the upper first coupling groove 211 and the lower first coupling groove 212,
The inner circumference of the upper second engagement groove 221 and the lower second engagement groove 222,
Each of the upper third coupling groove 231 and the lower third coupling groove 232 is provided with an electromagnet magnetized in accordance with whether a current is supplied from a current supplier 600 electrically connected to the controller 350 610)
Wherein each of the electromagnets (610) fixes the metal by a magnetic force when the magnet is rotated.

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