CN115126133A - Intelligent energy-saving curtain wall device for high-rise building - Google Patents

Abstract

The invention relates to the technical field of energy-saving curtain walls, in particular to an intelligent energy-saving curtain wall device for a high-rise building, which comprises a main mounting frame and a plurality of groups of curtain wall components, wherein each group of curtain wall components comprises an outer rectangular frame, a rectangular sealing strip, an inner rectangular frame, power generation glass, a driving device and two groups of adjusting devices, each group of adjusting devices comprises a strip-shaped adjusting plate, a transmission mechanism, a first connecting arm, a second connecting arm, a third connecting arm and a stabilizing arm, the end parts of the first connecting arm, the second connecting arm and the third connecting arm are fixedly connected with a sliding mechanism, a first sliding chute, a second sliding chute and a third sliding chute are formed on the strip-shaped adjusting plate, the inner rectangular frame can horizontally move away from a wall surface, outside air can enter the inner side of a curtain wall through the periphery of the inner rectangular frame to exchange heat, the inner rectangular frame can rotate and incline, so that the distance between the inner rectangular frame and the outer rectangular frame on the windward side is increased, the air can enter the inner side of the curtain wall to exchange heat.

Description

Intelligent energy-saving curtain wall device for high-rise building

Technical Field

The invention relates to the technical field of energy-saving curtain walls, in particular to an intelligent energy-saving curtain wall device for a high-rise building.

Background

The curtain wall is the enclosure of the outer wall of the building, does not bear the weight, is hung like a curtain, is also called as a curtain wall, and is a light wall with decorative effect commonly used by modern large and high-rise buildings. The building outer protective structure or decorative structure consists of a panel and a support structure system, can have certain displacement capacity or certain deformation capacity relative to the main structure, and does not bear the function of the main structure. Along with the high-speed development of national economy and the continuous improvement of the living standard of people in China and the improvement of the design concept of architects 'humanity is better than construction', buildings are developed to the direction of high-rise, high-grade and multifunctional more and more. Therefore, the building curtain wall product is inevitably developed towards high and new technology and multiple functions, so that the environmental protection and energy saving consciousness of people which is gradually enhanced can be adapted, and the requirement of the market on the functions of the building curtain wall is met. Present curtain is fixed mounting, and the air bed of sealing between curtain and wall can stop external thermal transmission, can effectual control indoor and outdoor difference in temperature when summer and winter, but when spring and autumn, outdoor temperature makes people's comfort improve, and the heat in the existence on air bed can not transmit to outdoor for indoor temperature improves and can make indoor personnel's comfort reduce on the contrary.

Disclosure of Invention

Therefore, it is necessary to provide an intelligent energy-saving curtain wall device for high-rise buildings in order to solve the problems in the prior art.

In order to solve the problems of the prior art, the invention adopts the technical scheme that: the utility model provides an energy-conserving formula curtain device of intelligent high-rise building, is the matrix form including fixing the total mounting bracket on the wall, still includes a plurality of groups and fixes the curtain subassembly on total mounting bracket, and every group curtain subassembly all includes:

the outer rectangular frame parallel to the wall surface is fixedly arranged on the main mounting frame, and a rectangular sealing strip is fixedly clamped on one side of the outer rectangular frame, which is far away from the wall surface;

the power generation glass is fixed on the inner rectangular frame, the inner rectangular frame is positioned on one side of the outer rectangular frame, which is far away from the wall surface, and the inner rectangular frame can be abutted against the rectangular sealing strip;

the wall surface adjusting device comprises a driving device and two groups of adjusting devices, wherein the driving device is fixedly arranged on one side, close to a wall surface, of an outer rectangular frame, the driving device is fixed on the vertical side edge of the outer rectangular frame, the two groups of adjusting devices are symmetrically and respectively fixedly arranged on two horizontal side edges of the outer rectangular frame, each group of adjusting devices comprises a horizontal strip-shaped adjusting plate, a transmission mechanism fixed on the outer rectangular frame, a first connecting arm, a second connecting arm, a third connecting arm and a horizontal stabilizing arm, the length direction of the strip-shaped adjusting plate is consistent with that of the horizontal side edge of the outer rectangular frame, the driving device drives the strip-shaped adjusting plate to slide along the length direction of the horizontal side edge of the outer rectangular frame through the transmission mechanism, the end parts of the first connecting arm, the second connecting arm and the third connecting arm are horizontally and rotatably connected with an inner rectangular frame and are all located above the strip-shaped adjusting plate, and the first connecting arm, the second connecting arm, the third connecting arm, and the third connecting arm, the third, The other end of the third connecting arm is fixedly connected with a sliding mechanism, three groups of sliding mechanisms are respectively and horizontally and rotatably connected with the two ends and the middle part of the stabilizing arm, the first connecting arm, the second connecting arm and the third connecting arm are all perpendicular to the outer rectangular frame, the second connecting arm is positioned between the first connecting arm and the second connecting arm, the third connecting arm is arranged close to the driving device, the second connecting arm is in sliding connection with the outer rectangular frame along the length direction of the second connecting arm, a first sliding groove is formed on the strip-shaped adjusting plate, the first connecting arm is connected with the first sliding groove in a sliding mode through the sliding mechanism, the second connecting arm is connected with the second sliding groove in a sliding mode through the sliding mechanism, the third connecting arm is connected with the third sliding groove in a sliding mode through the sliding mechanism, and the strip-shaped adjusting plate drives the stabilizing arm to rotate around the sliding mechanism in the middle after the stabilizing arm is close to the outer rectangular frame to slide when sliding and then rotates reversely.

Furthermore, the first chute is formed by sequentially communicating a first positioning portion, a first inclined portion, a first parallel portion, a second inclined portion, a second parallel portion and a third inclined portion, the first positioning portion, the first parallel portion and the second parallel portion are arranged in the same length direction as the strip-shaped adjusting plate, the end portion, close to the outer rectangular frame, of the first inclined portion is far away from the second connecting arm to incline, the second inclined portion inclines in the same direction as the first inclined portion, and the end portion, far away from the outer rectangular frame, of the third inclined portion is far away from the second connecting arm to incline.

Furthermore, the second sliding groove is formed by sequentially communicating a second positioning portion, a fourth inclined portion and a third parallel portion, the second positioning portion and the third parallel portion are in the same length direction with the strip-shaped adjusting plate, the second positioning portion and the first positioning portion are arranged in a collinear manner, the third parallel portion and the first parallel portion are arranged in a collinear manner, and the inclination angle of the third inclined portion is the same as that of the first inclined portion.

Furthermore, the third chute is formed by sequentially communicating a third positioning portion, a fifth inclined portion, a fourth parallel portion, a sixth inclined portion, a fifth parallel portion and a seventh inclined portion, the third positioning portion, the fourth parallel portion and the fifth parallel portion are all arranged in the same length direction as the strip-shaped adjusting plate, the third positioning portion and the first positioning portion are arranged in a collinear manner, the fifth parallel portion and the first parallel portion are arranged in a collinear manner, the inclination angle of the fifth inclined portion is the same as that of the first inclined portion, the inclination direction of the sixth inclined portion is opposite to that of the fifth inclined portion, and the inclination direction of the seventh inclined portion is the same as that of the fifth inclined portion.

Further, the slide mechanism includes:

the connecting sleeve is fixedly sleeved on the end part of the first connecting arm, and the upper end of the connecting sleeve is rotatably connected with the end part of the stabilizing arm through a vertical first connecting bolt;

the connecting frame is fixedly connected with the lower end of the connecting sleeve;

two groups of ball mechanisms which are symmetrically distributed about the strip-shaped adjusting plate are respectively connected with the top end and the bottom end of the strip-shaped adjusting plate in a sliding way, and the top end of the ball mechanism positioned above the ball mechanisms is contacted with the lower end of the connecting piece;

the vertical rectangular positioning sleeve is positioned in the first sliding chute, the lower end of the rectangular positioning sleeve downwards penetrates through the ball mechanism positioned below, and the upper end of the rectangular positioning sleeve upwards penetrates through the ball mechanism positioned above and is inserted into the connecting piece;

the inner pipe sleeve is sleeved on the rectangular positioning sleeve and is positioned in the first sliding chute, and two ends of the inner pipe sleeve respectively abut against the two groups of ball mechanisms;

the outer pipe sleeve is rotatably sleeved on the inner pipe sleeve and is in sliding connection with the first sliding chute;

the vertical second connecting bolt upwards penetrates through the rectangular positioning sleeve to be connected and fixed with the connecting frame in a rotating mode, a limiting gasket is sleeved on the lower end of the second connecting bolt, and the top end of the limiting gasket is abutted to the lower end of the rectangular positioning sleeve and the bottom end of the ball mechanism located below.

Further, the ball mechanism includes:

a vertical rectangular through groove is formed in the axis of the vertical cylindrical part, and the rectangular positioning sleeve penetrates through the rectangular through groove;

the ball bearing assembly comprises a plurality of ball bearings which are uniformly distributed along the circumferential direction of a cylindrical piece, wherein a plurality of accommodating grooves are formed in one side of the cylindrical piece close to a strip-shaped adjusting plate, and the plurality of ball bearings are correspondingly positioned in the plurality of accommodating grooves one by one;

and the limiting end cover is fixedly arranged on the end part of the cylindrical part close to the strip-shaped adjusting plate, each ball passes through the limiting end cover to be connected with the strip-shaped adjusting plate in a sliding manner, and the rectangular limiting sleeve passes through the limiting end cover.

Further, the transmission mechanism includes:

the rotary connection seat is fixed at the bottom of the strip-shaped adjusting plate and is arranged close to the driving device, a threaded rod which has the same length direction as the strip-shaped adjusting plate is screwed on the rotary connection seat, two ends of the threaded rod are both in shaft connection with the outer rectangular frame, and a first gear is fixedly sleeved on the end part of the threaded rod close to the driving device;

the connecting shaft which is in shaft connection with the outer rectangular frame and has the same length direction with the threaded rod is positioned between the threaded rod and the outer rectangular frame, a second gear meshed with the first gear is fixedly sleeved on the connecting shaft, a worm wheel connected with the driving device is fixedly sleeved on the connecting shaft, and the worm wheel is positioned on one side, close to the driving device, of the second gear.

Further, the driving device includes:

the double-shaft motor is fixed on the outer rectangular frame through a mounting frame;

two vertical worms are respectively fixedly connected with two output shafts of the double-shaft motor, the two worms are respectively coupled with the outer rectangular frame, and the two worms are respectively meshed with the worms in the two groups of adjusting devices.

Further, drive arrangement's outside cover is equipped with first shell, adjusting device's outside cover is equipped with the second shell, second shell and first shell all with outer rectangular frame fixed connection, first linking arm, second linking arm and third linking arm wear out the second shell and articulate with interior rectangular frame.

Compared with the prior art, the invention has the following beneficial effects: firstly, when the curtain wall is in a windless environment in spring and autumn, the inner rectangular frame can horizontally move away from the wall surface, and outside air can enter the inner side of the curtain wall through the periphery of the inner rectangular frame to exchange heat;

secondly, when the curtain wall is in a wind environment in spring and autumn, the inner rectangular frame can rotate and incline, the distance between the windward sides of the inner rectangular frame and the outer rectangular frame is increased, air can enter the inner side of the curtain wall to exchange heat, and the comfort of indoor personnel is improved;

thirdly, in summer and winter, the inner rectangular frame tightly props against the rectangular sealing strips, and an air layer between the curtain wall assembly and the wall surface can block the transfer of external heat, so that the temperature difference between the indoor and the outdoor is improved, and the use frequency of the air conditioner is reduced;

fourthly, the glass not only can be used by the double-shaft motor, but also can be used by users.

Drawings

FIG. 1 is a schematic perspective view of the embodiment;

FIG. 2 is a perspective view of a curtain wall assembly of an embodiment;

FIG. 3 is a schematic perspective view of an outer rectangular frame and a rectangular weather strip of the embodiment;

FIG. 4 is a schematic perspective view of the embodiment at A in FIG. 3;

FIG. 5 is a perspective view of the curtain wall assembly of the embodiment;

FIG. 6 is a partial perspective view of a curtain wall assembly of an embodiment;

FIG. 7 is a schematic perspective view of a strip-shaped adjustment plate according to an embodiment;

FIG. 8 is a first perspective view of the sliding mechanism of the embodiment;

FIG. 9 is a second perspective view of the sliding mechanism of the embodiment;

FIG. 10 is an exploded schematic view of a slide mechanism of the embodiment;

FIG. 11 is a schematic perspective view of the actuator and the strip-shaped adjustment plate according to the embodiment;

FIG. 12 is a partial perspective view of a curtain wall assembly of an embodiment;

FIG. 13 is a partial perspective view of a curtain wall assembly of an embodiment;

FIG. 14 is a partial perspective view of a curtain wall assembly of an embodiment.

The reference numbers in the figures are: 1. a total mounting frame; 2. power generation glass; 3. an outer rectangular frame; 4. a rectangular sealing strip; 5. an inner rectangular frame; 6. a strip-shaped adjusting plate; 7. a transmission mechanism; 8. a first connecting arm; 9. a second connecting arm; 10. a third connecting arm; 11. a stabilizing arm; 12. a sliding mechanism; 13. a first positioning portion; 14. a first inclined portion; 15. a first parallel portion; 16. a second inclined portion; 17. a second parallel portion; 18. a third inclined portion; 19. a second positioning portion; 20. a fourth inclined portion; 21. a third parallel portion; 22. a third positioning part; 23. a fifth inclined portion; 24. a fourth parallel portion; 25. a sixth slope portion; 26. a fifth parallel portion; 27. a seventh inclined portion; 28. connecting sleeves; 29. a first connecting bolt; 30. a connecting frame; 31. a rectangular positioning sleeve; 32. an inner pipe sleeve; 33. an outer pipe sleeve; 34. a second connecting bolt; 35. a limiting gasket; 36. a cylindrical member; 37. a rectangular through groove; 38. a ball bearing; 39. an accommodating recess; 40. a limiting end cover; 41. a screwing seat; 42. a threaded rod; 43. a first gear; 44. a connecting shaft; 45. a second gear; 46. a worm gear; 47. a double-shaft motor; 48. a mounting frame; 49. a worm; 50. a first housing; 51. a second housing; 52. a first chute; 53. a second chute; 54. and a third chute.

Detailed Description

For further understanding of the features and technical means of the present invention, as well as the specific objects and functions attained by the present invention, the present invention will be described in further detail with reference to the accompanying drawings and detailed description.

Referring to fig. 1 to 14, an intelligent energy-saving curtain wall device for high-rise buildings comprises a general mounting frame 1 fixed on a wall surface, and further comprises a plurality of groups of curtain wall assemblies fixed on the general mounting frame 1 in a matrix shape, wherein each group of curtain wall assemblies comprises:

an outer rectangular frame 3 parallel to the wall surface is fixedly arranged on the main mounting frame 1, and a rectangular sealing strip 4 is fixedly clamped on one side, far away from the wall surface, of the outer rectangular frame 3;

the power generation glass 2 is fixed on the inner rectangular frame 5, the inner rectangular frame 5 is positioned on one side, away from the wall surface, of the outer rectangular frame 3, and the inner rectangular frame 5 can abut against the rectangular sealing strip 4;

the wall surface adjusting device comprises a driving device and two groups of adjusting devices, wherein the driving device is fixedly arranged on one side, close to a wall surface, of an outer rectangular frame 3, the driving device is fixed on the vertical side edge of the outer rectangular frame 3, the two groups of adjusting devices are symmetrically and respectively fixedly arranged on two horizontal side edges of the outer rectangular frame 3, each group of adjusting devices comprises a horizontal strip-shaped adjusting plate 6, a transmission mechanism 7 fixed on the outer rectangular frame 3, a first connecting arm 8, a second connecting arm 9, a third connecting arm 10 and a horizontal stabilizing arm 11, the length direction of the strip-shaped adjusting plate 6 is consistent with that of the horizontal side edge of the outer rectangular frame 3, the driving device drives the strip-shaped adjusting plate 6 to slide along the length direction of the horizontal side edge of the outer rectangular frame 3 through the transmission mechanism 7, the end parts of the first connecting arm 8, the second connecting arm 9 and the third connecting arm 10 are horizontally and rotatably connected with an inner rectangular frame 5 and are all positioned above the strip-shaped adjusting plate 6, the other ends of the first connecting arm 8, the second connecting arm 9 and the third connecting arm 10 are fixedly connected with sliding mechanisms 12, three groups of sliding mechanisms 12 are respectively connected with two ends and the middle part of a stabilizing arm 11 in a horizontal rotating manner, the first connecting arm 8, the second connecting arm 9 and the third connecting arm 10 are all perpendicular to the outer rectangular frame 3, the second connecting arm 9 is positioned between the first connecting arm 8 and the second connecting arm 9, the third connecting arm 10 is arranged close to the driving device, the second connecting arm 9 is connected with the outer rectangular frame 3 in a sliding manner along the length direction, a first sliding groove 52, a second sliding groove 53 and a third sliding groove 54 are formed on the strip-shaped adjusting plate 6, the first connecting arm 8 is connected with the first sliding groove 52 in a sliding manner through a sliding mechanism 12, the second connecting arm 9 is connected with the second sliding groove 53 through the sliding mechanism 12, the third connecting arm 10 is connected with the third sliding groove 54 through the sliding mechanism 12, the strip-shaped adjusting plate 6 drives the stabilizing arm 11 to rotate around the middle sliding mechanism 12 after sliding close to the outer rectangular frame 3 and then reversely rotate when sliding.

The intelligent energy-saving curtain wall device for the high-rise building further comprises a control terminal and a wind direction detection mark, wherein the control terminal and the wind direction detection mark are both in the prior art and are not shown in the drawing, and the wind direction detection mark is used for monitoring the wind direction.

The power generation glass 2 converts solar energy into electric energy, can be used by a driving device in spring and autumn, and can supply power to users in winter and summer.

When winter and summer, drive arrangement need not start, and the tight conflict of interior rectangular frame 5 is on rectangular sealing strip 4, and the curtain subassembly separates external space, is confined air bed between curtain subassembly and the wall, and the air bed can completely cut off external thermal transmission, increases indoor and outdoor difference in temperature, reduces the frequency of utilization of air conditioner.

In spring and autumn, the control terminal controls the driving device to start, the transmission mechanism 7 drives the strip-shaped adjusting plate 6 to horizontally slide, the first sliding groove 52, the second sliding groove 53 and the third sliding groove 54 are different, the strip-shaped adjusting plate 6 slides into three sections, the three sections of sliding respectively correspond to three moving states of the stabilizing arm 11, the stabilizing arm 11 moves horizontally close to the outer rectangular frame 3 when the first section slides, the end part, connected with the first connecting arm 8, of the stabilizing arm 11 rotates close to the outer rectangular frame 3 around the sliding mechanism 12 in the middle part when the second section slides, and the end part, connected with the first connecting arm 8, of the stabilizing arm 11 rotates far away from the outer rectangular frame 3 around the sliding mechanism 12 in the middle part when the third section slides.

When the first section of the strip-shaped adjusting plate 6 slides, the three groups of sliding mechanisms 12 respectively slide in the first sliding groove 52, the second sliding groove 53 and the third sliding groove 54, the first connecting arm 8, the second connecting arm 9 and the third connecting arm 10 slide along the length direction of the first connecting arm away from the wall surface, the inner rectangular frame 5 is pushed out towards the far away wall surface, outside air enters the space between the wall surface and the outer rectangular frame 3 through the space between the inner rectangular frame 5 and the outer rectangular frame 3, the air entering the space between the wall surface and the outer rectangular frame 3 can exchange heat with the inside air, the temperature of the wall surface is adjusted, the indoor and outdoor temperature difference is reduced, the outer rectangular frame 3 and the inner rectangular frame 5 are parallel at the moment, and the strip-shaped adjusting plate is suitable for a windless environment.

When the strip-shaped adjusting plate 6 slides to the first section, the strip-shaped adjusting plate 6 slides for the second section, the second connecting arm 9 does not slide, the second connecting arm 9 is connected with the outer rectangular frame 3 in a sliding manner along the length direction of the strip-shaped adjusting plate, the first connecting arm 8 and the third connecting arm 10 are always parallel to the second connecting arm 9, the second connecting arm 9 starts positioning, the stabilizing arm 11 rotates around the sliding mechanism 12 in the middle, the first connecting arm 8 and the third connecting arm 10 slide close to the second connecting arm 9, the first connecting arm 8 slides away from the wall surface, the third connecting arm 10 slides close to the wall surface to drive the inner rectangular frame 5 to incline, the gap between the inner rectangular frame 5 and one side of the outer rectangular frame 3 is increased, inclined wind can enter the outer rectangular frame 3 to exchange heat with the wall surface, and similarly, when the strip-shaped adjusting plate 6 slides for the third section, second linking arm 9 is motionless, and the steady arm 11 is rotatory around the slide mechanism 12 that is located in the middle of being located, and first linking arm 8 is close to the wall and slides, and third linking arm 10 keeps away from the wall and slides for the incline direction of interior rectangular frame 5 when the incline direction of interior rectangular frame 5 slides is opposite with the incline direction of interior rectangular frame 5 when the second section slides, does benefit to and gets into between outer rectangular frame 3 and the wall from the wind of opposite side direction, makes interior rectangular frame 5 can adjust inclination according to the wind direction.

The first sliding chute 52 is formed by sequentially communicating a first positioning portion 13, a first inclined portion 14, a first parallel portion 15, a second inclined portion 16, a second parallel portion 17 and a third inclined portion 18, the first positioning portion 13, the first parallel portion 15 and the second parallel portion 17 are all arranged in the same length direction as the strip-shaped adjusting plate 6, the end portion, close to the outer rectangular frame 3, of the first inclined portion 14 is inclined away from the second connecting arm 9, the second inclined portion 16 is inclined in the same direction as the first inclined portion 14, and the end portion, far away from the outer rectangular frame 3, of the third inclined portion 18 is inclined away from the second connecting arm 9.

The second chute 53 is formed by sequentially communicating a second positioning portion 19, a fourth inclined portion 20 and a third parallel portion 21, the second positioning portion 19 and the third parallel portion 21 are both in the same length direction as the strip-shaped adjusting plate 6, the second positioning portion 19 is arranged in line with the first positioning portion 13, the third parallel portion 21 is arranged in line with the first parallel portion 15, and the third inclined portion 18 is arranged at the same inclination angle as the first inclined portion 14.

The third chute 54 is formed by sequentially communicating a third positioning portion 22, a fifth inclined portion 23, a fourth parallel portion 24, a sixth inclined portion 25, a fifth parallel portion 26 and a seventh inclined portion 27, the third positioning portion 22, the fourth parallel portion 24 and the fifth parallel portion 26 are all arranged in the same length direction as the strip-shaped adjusting plate 6, the third positioning portion 22 is arranged in line with the first positioning portion 13, the fifth parallel portion 26 is arranged in line with the first parallel portion 15, the inclined angle of the fifth inclined portion 23 is the same as that of the first inclined portion 14, the inclined direction of the sixth inclined portion 25 is opposite to that of the fifth inclined portion 23, and the inclined direction of the seventh inclined portion 27 is the same as that of the fifth inclined portion 23.

When the inner rectangular frame 5 abuts on the rectangular weather strip 4, the first connecting arm 8 is located in the first positioning portion 13, the second connecting arm 9 is located in the second positioning portion 19, and the third connecting arm 10 is located in the third positioning portion 22.

When the strip-shaped adjusting plate 6 slides for the first period, the first connecting arm 8 slides from the first positioning portion 13 into the first inclined portion 14, the first connecting arm 8 slides away from the wall surface, when the strip-shaped adjusting plate slides into the first parallel portion 15, the first connecting arm 8 keeps the state of the first connecting arm, the second connecting arm 9 slides from the second positioning portion 19 into the fourth inclined portion 20, the second connecting arm 9 slides away from the wall surface, when the strip-shaped adjusting plate slides into the third parallel portion 21, the second connecting arm 9 keeps the state of the second connecting arm, the third connecting arm 10 slides from the third positioning portion 22 into the fifth inclined portion 23, the third connecting arm 10 slides away from the wall surface, when the strip-shaped adjusting plate slides into the fourth parallel portion 24, the third connecting arm 10 keeps the state of the third connecting arm, and because the first parallel portion 15, the third parallel portion 21 and the fourth parallel portion 24 are collinear, the inner rectangular frame 5 and the outer rectangular frame 3 remain parallel after being separated.

When the strip-shaped adjusting plate 6 slides for the second period, the first connecting arm 8 slides into the second inclined portion 16 from the first parallel portion 15, the first connecting arm 8 slides away from the wall surface, the first connecting arm 8 slides into the second parallel portion 17 and keeps the same, the second connecting arm 9 continues to slide in the third parallel portion 21, the second connecting arm 9 keeps the same, the third connecting arm 10 slides into the sixth inclined portion 25 from the fourth parallel portion 24, the third connecting arm 10 slides close to the wall surface, the third connecting arm 10 slides into the fifth parallel portion 26 and keeps the same, at this time, the inner rectangular frame 5 is in an inclined state, the distance between the inner rectangular frame 5 and the outer rectangular frame 3 close to the first connecting arm 8 is increased, and the distance between the inner rectangular frame 5 and the outer rectangular frame 3 close to the third connecting arm 10 is decreased.

When the strip-shaped adjusting plate 6 performs the third-stage sliding, the first connecting arm 8 slides into the third inclined portion 18 from the second parallel portion 17, the first connecting arm 8 slides close to the wall surface until the first connecting arm 8 slides to the end portion of the third inclined portion 18, the second connecting arm 9 still slides in the third parallel portion 21, the second connecting arm 9 remains stationary, the third connecting arm 10 slides into the seventh inclined portion 27 from the fifth parallel portion 26, the third connecting arm 10 slides away from the wall surface until the third connecting arm 10 slides to the end portion of the seventh inclined portion 27, at this time, the inclination direction of the inner rectangular frame 5 is opposite to the inclination direction of the inner rectangular frame 5 during the second sliding, the distance between the inner rectangular frame 5 and the outer rectangular frame 3 on the side close to the first connecting arm 8 decreases, and the distance between the inner rectangular frame 5 and the outer rectangular frame 3 on the side close to the third connecting arm 10 increases.

The slide mechanism 12 includes:

the connecting sleeve 28 is fixedly sleeved on the end part of the first connecting arm 8, and the upper end of the connecting sleeve 28 is rotatably connected with the end part of the stabilizing arm 11 through a vertical first connecting bolt 29;

the connecting frame 30 is fixedly connected with the lower end of the connecting sleeve 28;

two groups of ball mechanisms which are symmetrically distributed about the strip-shaped adjusting plate 6 are respectively connected with the top end and the bottom end of the strip-shaped adjusting plate 6 in a sliding way, and the top end of the ball mechanism positioned above is contacted with the lower end of the connecting piece;

the vertical rectangular positioning sleeve 31 is positioned in the first sliding chute 52, the lower end of the rectangular positioning sleeve 31 downwards penetrates through the ball mechanism positioned below, and the upper end of the rectangular positioning sleeve 31 upwards penetrates through the ball mechanism positioned above and is inserted into the connecting piece;

the inner pipe sleeve 32 is sleeved on the rectangular positioning sleeve 31 and is positioned in the first sliding groove 52, and two ends of the inner pipe sleeve 32 are respectively abutted against the two groups of ball mechanisms;

the outer pipe sleeve 33 is rotatably sleeved on the inner pipe sleeve 32, and the outer pipe sleeve 33 is connected with the first sliding chute 52 in a sliding manner;

the vertical second connecting bolt 34 upwards passes through the rectangular positioning sleeve 31 and is screwed and fixed with the connecting frame 30, the lower end of the second connecting bolt 34 is sleeved with a limiting gasket 35, and the top end of the limiting gasket 35 is abutted to the lower end of the rectangular positioning sleeve 31 and the bottom end of the ball mechanism located below.

The ball mechanism includes:

a vertical cylindrical part 36, wherein a vertical rectangular through groove 37 is formed at the axis, and the rectangular positioning sleeve 31 passes through the rectangular through groove 37;

the ball bearings 38 are uniformly distributed along the circumferential direction of the cylindrical member 36, a plurality of accommodating grooves 39 are formed in one side of the cylindrical member 36 close to the strip-shaped adjusting plate 6, and the ball bearings 38 are correspondingly positioned in the accommodating grooves 39 one by one;

and the limiting end cover 40 is fixedly arranged on the end part of the cylindrical part 36 close to the strip-shaped adjusting plate 6, each ball 38 penetrates through the limiting end cover 40 to be in sliding connection with the strip-shaped adjusting plate 6, and the rectangular limiting sleeve penetrates through the limiting end cover 40.

When strip regulation plate 6 horizontal slip, outer pipe sleeve 33 can rotate on inner pipe sleeve 32, can reduce the sliding friction of outer pipe sleeve 33, outer pipe sleeve 33 slides in first spout 52, rectangle position sleeve 31 inserts in rectangle logical groove 37, restriction cylinder 36 is unable rotatory, and the both ends of inner pipe sleeve 32 are contradicted with two sets of ball mechanism respectively, fix two sets of ball mechanism, two sets of ball mechanism and strip regulation plate 6's both sides sliding connection, can also prevent sliding mechanism 12 slippage from starting limiting displacement.

Since the shapes of the first sliding chute 52, the second sliding chute 53 and the third sliding chute 54 are all inconsistent, a plurality of balls 38 are required to slide on the strip-shaped adjusting plate 6, so that the sliding mechanism 12 can slide on the strip-shaped adjusting plate 6 in any direction.

The transmission mechanism 7 includes:

a screwing seat 41 fixed on the bottom of the strip-shaped adjusting plate 6 and arranged close to the driving device, a threaded rod 42 with the same length direction as the strip-shaped adjusting plate 6 is screwed on the screwing seat 41, two ends of the threaded rod 42 are both connected with the outer rectangular frame 3 in a shaft way, and a first gear 43 is fixedly sleeved on the end part of the threaded rod 42 close to the driving device;

and a connecting shaft 44 which is in the same length direction as the threaded rod 42 and is in shaft connection with the outer rectangular frame 3 is positioned between the threaded rod 42 and the outer rectangular frame 3, a second gear 45 meshed with the first gear 43 is fixedly sleeved on the connecting shaft 44, a worm wheel 46 connected with a driving device is fixedly sleeved on the connecting shaft 44, and the worm wheel 46 is positioned on one side, close to the driving device, of the second gear 45.

The driving device is started to drive the worm gear 46 to rotate, the worm gear 46 drives the connecting shaft 44 to rotate, and then drives the second gear 45 to rotate, the second gear 45 drives the threaded rod 42 to rotate through the first gear 43, and the threaded rod 42 rotates to drive the rotary connection seat 41 and the strip-shaped adjusting plate 6 to horizontally move.

The driving device includes:

a biaxial motor 47 fixed to the outer rectangular frame 3 through a mounting bracket 48;

two vertical worms 49 are respectively fixedly connected with two output shafts of the double-shaft motor 47, the two worms 49 are respectively coupled with the outer rectangular frame 3, and the two worms 49 are respectively meshed with the worms 49 in the two groups of adjusting devices.

The dual-shaft motor 47 is activated to rotate the two worms 49, and thus the two worm wheels 46.

Drive arrangement's outside cover is equipped with first shell 50, adjusting device's outside cover is equipped with second shell 51, second shell 51 and first shell 50 all with outer rectangular frame 3 fixed connection, first linking arm 8, second linking arm 9 and third linking arm 10 wear out second shell 51 and interior rectangular frame 5 articulated, and first shell 50 and second shell 51 are used for dustproof.

The working principle is as follows: the wind direction can be detected out to the wind direction detection mark, and control terminal controls biax motor 47 according to the information control of wind direction detection mark and starts, and electricity generation glass 2 not only can supply drive arrangement to use in spring and autumn with solar energy conversion's electric energy, can also supply power for the user when winter and summer.

When winter and summer, drive arrangement need not start, the tight conflict of interior rectangular frame 5 is on rectangular sealing strip 4, the curtain subassembly is separated external space, be confined air bed between curtain subassembly and the wall, the air bed can completely cut off external thermal transmission, increase indoor and outdoor difference in temperature, reduce with human comfort, cooperation variable frequency air conditioner uses, the operating frequency and the operating duration that can effectual reduction air conditioner, reduce the power consumption of air conditioner.

The double-shaft motor 47 is started to drive the worm 49 to rotate, so as to drive the worm wheel 46 to rotate, the worm wheel 46 drives the connecting shaft 44 to rotate, so as to drive the second gear 45 to rotate, the second gear 45 drives the threaded rod 42 to rotate through the first gear 43, and the threaded rod 42 drives the screwing seat 41 and the strip-shaped adjusting plate 6 to horizontally move in a rotating mode.

When the strip-shaped adjusting plate 6 slides for the first section, the first connecting arm 8 slides from the first positioning portion 13 into the first inclined portion 14, the first connecting arm 8 slides away from the wall surface, when sliding into the first horizontal portion, the first connecting arm 8 keeps the state of the first connecting arm, the second connecting arm 9 slides from the second positioning portion 19 into the fourth inclined portion 20, the second connecting arm 9 slides away from the wall surface, when sliding into the third parallel portion 21, the second connecting arm 9 keeps the state of the second connecting arm, the third connecting arm 10 slides from the third positioning portion 22 into the fifth inclined portion 23, the third connecting arm 10 slides away from the wall surface, when sliding into the fourth parallel portion 24, the third connecting arm 10 keeps the state of the third connecting arm, and because the first parallel portion 15, the third parallel portion 21 and the fourth parallel portion 24 are collinear, the inner rectangular frame 5 and the outer rectangular frame 3 keep parallel after being separated.

When the strip-shaped adjusting plate 6 slides for the second period, the first connecting arm 8 slides into the second inclined portion 16 from the first parallel portion 15, the first connecting arm 8 slides away from the wall surface, the first connecting arm 8 slides into the second parallel portion 17 and keeps the same, the second connecting arm 9 continues to slide in the third parallel portion 21, the second connecting arm 9 keeps the same, the third connecting arm 10 slides into the sixth inclined portion 25 from the fourth parallel portion 24, the third connecting arm 10 slides close to the wall surface, the third connecting arm 10 slides into the fifth parallel portion 26 and keeps the same, at this time, the inner rectangular frame 5 is in an inclined state, the distance between the inner rectangular frame 5 and the outer rectangular frame 3 close to the first connecting arm 8 is increased, and the distance between the inner rectangular frame 5 and the outer rectangular frame 3 close to the third connecting arm 10 is decreased.

When the strip-shaped adjusting plate 6 performs third-stage sliding, the first connecting arm 8 slides into the third inclined portion 18 from the second parallel portion 17, the first connecting arm 8 slides close to the wall surface until the first connecting arm 8 slides to the end portion of the third inclined portion 18, the second connecting arm 9 still slides in the third parallel portion 21, the second connecting arm 9 remains stationary, the third connecting arm 10 slides into the seventh inclined portion 27 from the fifth parallel portion 26, the third connecting arm 10 slides away from the wall surface until the third connecting arm 10 slides to the end portion of the seventh inclined portion 27, at this time, the inclination direction of the inner rectangular frame 5 is opposite to the inclination direction of the inner rectangular frame 5 during second sliding, the distance between the inner rectangular frame 5 and the outer rectangular frame 3 close to the first connecting arm 8 is reduced, and the distance between the inner rectangular frame 5 and the outer rectangular frame 3 close to the third connecting arm 10 is increased.

The above examples, which are intended to represent only one or more embodiments of the present invention, are described in greater detail and with greater particularity, and are not to be construed as limiting the scope of the invention. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the inventive concept, which falls within the scope of the present invention. Therefore, the protection scope of the present patent shall be subject to the appended claims.

Claims (9)

1. The utility model provides an energy-conserving formula curtain device of intelligent high-rise building, is including fixing total mounting bracket (1) on the wall, its characterized in that still includes that a plurality of groups are the curtain subassembly of matrix form fixing on total mounting bracket (1), and every group curtain subassembly all includes:

the outer rectangular frame (3) parallel to the wall surface is fixedly arranged on the main mounting frame (1), and a rectangular sealing strip (4) is fixedly clamped on one side, away from the wall surface, of the outer rectangular frame (3);

the power generation glass (2) is fixed on the inner rectangular frame (5), the inner rectangular frame (5) is positioned on one side, far away from the wall surface, of the outer rectangular frame (3), and the inner rectangular frame (5) can abut against the rectangular sealing strips (4);

drive arrangement and two sets of adjusting device, all fixed setting is close to one side of wall in outer rectangular frame (3), drive arrangement fixes on the vertical side of outer rectangular frame (3), two sets of adjusting device are the symmetry form and fix respectively and set up on two horizontal sides of outer rectangular frame (3), every adjusting device of group all includes horizontally strip regulating plate (6), fixed drive mechanism (7) on outer rectangular frame (3), first linking arm (8), second linking arm (9), third linking arm (10) and horizontally stabilize arm (11), the length direction of strip regulating plate (6) is unanimous with the length direction of the horizontal side of outer rectangular frame (3), drive arrangement passes through drive mechanism (7) and drives strip regulating plate (6) and slides along the length direction of outer rectangular frame (3) horizontal side, first linking arm (8) Second linking arm (9), third linking arm (10) tip all rotates with interior rectangular frame (5) level and is connected and all is located the top of strip regulating plate (6), first linking arm (8), second linking arm (9), equal fixedly connected with slide mechanism (12) on the other end of third linking arm (10), three group's slide mechanism (12) rotate with the both ends and the middle part level of stabilizing arm (11) respectively and are connected, first linking arm (8), second linking arm (9) and third linking arm (10) all rotate with the both ends and the middle part level of outer rectangular frame (3) is perpendicular and second linking arm (9) are located between first linking arm (8) and second linking arm (9), third linking arm (10) are close to drive arrangement setting, second linking arm (9) are along self length direction and outer rectangular frame (3) sliding connection, the shaping has first spout (52) on strip regulating plate (6), The first connecting arm (8) is connected with the first sliding groove (52) in a sliding mode through a sliding mechanism (12), the second connecting arm (9) is connected with the second sliding groove (53) in a sliding mode through the sliding mechanism (12), the third connecting arm (10) is connected with the third sliding groove (54) in a sliding mode through the sliding mechanism (12), and the strip-shaped adjusting plate (6) drives the stabilizing arm (11) to rotate around the sliding mechanism (12) in the middle after being close to the outer rectangular frame (3) to slide and then rotate reversely when sliding.

2. The intelligent energy-saving curtain wall device for the high-rise building as claimed in claim 1, wherein the first chute (52) is formed by sequentially communicating a first positioning part (13), a first inclined part (14), a first parallel part (15), a second inclined part (16), a second parallel part (17) and a third inclined part (18), the first positioning part (13), the first parallel part (15) and the second parallel part (17) are all arranged in the same length direction as the strip-shaped adjusting plate (6), the end part of the first inclined part (14) close to the outer rectangular frame (3) is inclined away from the second connecting arm (9), the second inclined part (16) is inclined in the same direction as the first inclined part (14), and the end part of the third inclined part (18) far away from the outer rectangular frame (3) is inclined away from the second connecting arm (9).

3. The intelligent energy-saving curtain wall device for the high-rise building as claimed in claim 2, wherein the second chute (53) is formed by sequentially communicating a second positioning part (19), a fourth inclined part (20) and a third parallel part (21), the second positioning part (19) and the third parallel part (21) are both in the same length direction as the strip-shaped adjusting plate (6), the second positioning part (19) and the first positioning part (13) are arranged in a collinear manner, the third parallel part (21) and the first parallel part (15) are arranged in a collinear manner, and the inclined angle of the third inclined part (18) and the first inclined part (14) is the same.

4. The intelligent energy-saving curtain wall device for high-rise buildings according to claim 3, the third chute (54) is formed by sequentially communicating a third positioning part (22), a fifth inclined part (23), a fourth parallel part (24), a sixth inclined part (25), a fifth parallel part (26) and a seventh inclined part (27), the third positioning part (22), the fourth parallel part (24) and the fifth parallel part (26) are all arranged in the same length direction as the strip-shaped adjusting plate (6), the third positioning part (22) and the first positioning part (13) are arranged in a collinear manner, the fifth parallel part (26) and the first parallel part (15) are arranged in a collinear manner, the fifth inclined part (23) and the first inclined part (14) have the same inclination angle, the sixth inclined part (25) and the fifth inclined part (23) have opposite inclination directions, and the seventh inclined part (27) and the fifth inclined part (23) have the same inclination direction.

5. The intelligent energy-saving curtain wall device for the high-rise building as claimed in claim 1, wherein the sliding mechanism (12) comprises:

the connecting sleeve (28) is fixedly sleeved on the end part of the first connecting arm (8), and the upper end of the connecting sleeve (28) is rotatably connected with the end part of the stabilizing arm (11) through a vertical first connecting bolt (29);

the connecting frame (30) is fixedly connected with the lower end of the connecting sleeve (28);

two groups of ball mechanisms which are symmetrically distributed about the strip-shaped adjusting plate (6) are respectively connected with the top end and the bottom end of the strip-shaped adjusting plate (6) in a sliding way, and the top end of the ball mechanism positioned above is contacted with the lower end of the connecting piece;

the vertical rectangular positioning sleeve (31) is positioned in the first sliding groove (52), the lower end of the rectangular positioning sleeve (31) downwards penetrates through the ball mechanism positioned below, and the upper end of the rectangular positioning sleeve (31) upwards penetrates through the ball mechanism positioned above and is inserted into the connecting piece;

the inner pipe sleeve (32) is sleeved on the rectangular positioning sleeve (31) and is positioned in the first sliding groove (52), and two ends of the inner pipe sleeve (32) are respectively abutted against the two groups of ball mechanisms;

the outer pipe sleeve (33) is rotatably sleeved on the inner pipe sleeve (32), and the outer pipe sleeve (33) is connected with the first sliding chute (52) in a sliding manner;

the vertical second connecting bolt (34) penetrates the rectangular positioning sleeve (31) upwards and is fixedly connected with the connecting frame (30) in a screwing mode, a limiting gasket (35) is sleeved on the lower end of the second connecting bolt (34), and the top end of the limiting gasket (35) is abutted to the lower end of the rectangular positioning sleeve (31) and the bottom end of the ball mechanism located below.

6. The intelligent energy-saving curtain wall device for the high-rise building as claimed in claim 5, wherein the ball mechanism comprises:

a vertical rectangular through groove (37) is formed in the axis of the vertical cylindrical piece (36), and the rectangular positioning sleeve (31) penetrates through the rectangular through groove (37);

the ball bearing assembly comprises a plurality of balls (38) which are uniformly distributed along the circumferential direction of a cylindrical piece (36), a plurality of accommodating grooves (39) are formed in one side, close to a strip-shaped adjusting plate (6), of the cylindrical piece (36), and the balls (38) are located in the accommodating grooves (39) in a one-to-one correspondence mode;

and the limiting end covers (40) are fixedly arranged on the end parts, close to the strip-shaped adjusting plates (6), of the cylindrical pieces (36), each ball (38) penetrates through the limiting end covers (40) to be in sliding connection with the strip-shaped adjusting plates (6), and the rectangular limiting sleeves penetrate through the limiting end covers (40).

7. The intelligent energy-saving curtain wall device for the high-rise building according to claim 1, wherein the transmission mechanism (7) comprises:

a rotary connection seat (41) fixed at the bottom of the strip-shaped adjusting plate (6) and arranged close to the driving device, a threaded rod (42) with the same length direction as the strip-shaped adjusting plate (6) is in rotary connection with the rotary connection seat (41), two ends of the threaded rod (42) are in shaft connection with the outer rectangular frame (3), and a first gear (43) is fixedly sleeved on the end part of the threaded rod (42) close to the driving device;

with threaded rod (42) with length direction and with outer rectangular frame (3) coupling connecting axle (44), be located between threaded rod (42) and outer rectangular frame (3), fixed cover is equipped with second gear (45) with first gear (43) meshing on connecting axle (44), still fixed cover is equipped with worm wheel (46) be connected with drive arrangement on connecting axle (44), worm wheel (46) are located one side that second gear (45) are close to drive arrangement.

8. The intelligent energy-saving curtain wall device for the high-rise building as claimed in claim 7, wherein the driving device comprises:

the double-shaft motor (47) is fixed on the outer rectangular frame (3) through a mounting rack (48);

two vertical worms (49) are respectively and fixedly connected with two output shafts of the double-shaft motor (47), the two worms (49) are respectively in shaft connection with the outer rectangular frame (3), and the two worms (49) are respectively meshed with the worms (49) in the two groups of adjusting devices.

9. The intelligent energy-saving curtain wall device for the high-rise building according to claim 1, wherein a first shell (50) is sleeved on the outer side of the driving device, a second shell (51) is sleeved on the outer side of the adjusting device, the second shell (51) and the first shell (50) are fixedly connected with the outer rectangular frame (3), and the first connecting arm (8), the second connecting arm (9) and the third connecting arm (10) penetrate out of the second shell (51) and are hinged to the inner rectangular frame (5).

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