CN112012390B

CN112012390B - Energy-saving movable deformation roof structure

Info

Publication number: CN112012390B
Application number: CN202010736638.7A
Authority: CN
Inventors: 王育晓; 林赛多
Original assignee: Individual
Current assignee: Individual
Priority date: 2020-07-28
Filing date: 2020-07-28
Publication date: 2022-01-25
Anticipated expiration: 2040-07-28
Also published as: CN112012390A

Abstract

The invention discloses an energy-saving movable deformable roof structure, which has the technical scheme that: the front panel and the rear panel are supported at the upper end of the building through deformation components at the lower ends of the two sides, the front panel and the rear panel are symmetrical to each other, the deformation components are provided with two supporting ends, the front panel and the rear panel are fixed on the supporting ends respectively, a servo motor is arranged in the deformation components, the servo motor rotates to drive the supporting ends to move, the front panel and the rear panel comprise inner plates and outer plates, the inner plates are inserted into the outer plates, push-pull components are arranged in the outer plates, and push-pull plates of the push-pull components are fixed with the inner plates.

Description

Energy-saving movable deformation roof structure

Technical Field

The invention relates to the field of building roofs, in particular to an energy-saving movable deformable roof structure.

Background

The roof has not only just played the effect of thermal-insulated keeping off the rain in present era, and to tourist attraction or sunshine room, the effect of roof just need be under thermal-insulated basis that keeps off the rain, plays better decorative effect and the special effect that plays through deformation to current roof does not have a section and can match the sunshine room through warping, plays the roof and opens and form the sunshine room, and the roof is closed and is played the sunshade effect of keeping off the rain, therefore designs the very necessary of a section energy-saving roof structure that can move the deformation.

Disclosure of Invention

Aiming at the defects in the prior art, the invention aims to provide an energy-saving movable deformation roof structure which can realize the opening and closing and the extension of a roof through deformation.

In order to achieve the purpose, the invention provides the following technical scheme:

the energy-saving movable deformable roof structure comprises a building house and a deformable roof, wherein the deformable roof comprises a front panel and a rear panel, the front panel and the rear panel are supported at the upper end of the building house through deformation components at the lower ends of two sides and are symmetrical with each other, the deformation components are provided with two supporting ends, the front panel and the rear panel are respectively fixed on the supporting ends, a servo motor is arranged in the deformation components, the servo motor rotates to drive the supporting ends to move, the front panel and the rear panel respectively comprise an inner plate block and an outer plate block, the inner plate block is inserted in the outer plate block, a push-pull component is arranged in the outer plate block, and a push-pull plate of the push-pull component is fixed with the inner plate block.

Further, the deformation component comprises a servo motor, a screw rod, a left moving rod, a right moving rod, a moving sleeve, a left moving block and a right moving block, the front end of the servo motor is sleeved with a shaft sleeve, the screw rod passes through a shaft hole of the shaft sleeve to be connected with the servo motor, the shaft sleeve is fixed on the servo motor and is not contacted with the screw rod, a left moving rod and a right moving rod are fixed at the two symmetrical ends of the shaft sleeve, the left moving rod and the right moving rod are respectively sleeved with a left moving block and a right moving block, the screw rod is screwed with a moving sleeve, the moving sleeve is provided with an inner thread groove matched with the outer thread of the screw, the moving sleeve and the left moving block and the right moving block are penetrated by a connecting rod to move synchronously, and supporting plates are respectively fixed at the supporting ends of the left moving block and the right moving block, and the supporting plates on the left moving block and the right moving block are respectively connected with the front panel and the rear panel through telescopic components.

Furthermore, the telescopic assembly comprises an upper telescopic connecting rod and a lower telescopic connecting rod, a telescopic head of the upper telescopic connecting rod is fixed at the lower end of the inner plate, a telescopic head of the lower telescopic connecting rod is fixed at the lower end of the outer plate, the upper telescopic connecting rod and the lower telescopic connecting rod are both positioned in the support plate, the lower telescopic connecting rod is fixed in the support plate, and the upper telescopic connecting rod is slidably connected in the support plate.

Furthermore, be equipped with the spout in the backup pad, the spout is protruding type, the lower extreme of going up telescopic link is fixed with the slider, the slider matches the slip setting in the spout.

Furthermore, the push-pull assembly comprises a cylinder, the head of the cylinder is fixed with the push-pull plate, and the push-pull plate is fixed with the bottom end of the inner plate block.

Furthermore, a plurality of rollers are connected to the outer ends of the two sides of the inner plate, rolling grooves are formed in the two sides of the inner end of the outer plate, and the rollers are arranged in the rolling grooves in a matched mode.

Furthermore, a plurality of solar charging panels which are uniformly distributed are arranged on the upper end face of the outer plate, the solar charging panels are all connected with a storage battery, and the storage battery is respectively and electrically connected with the cylinder, the servo motor, the upper telescopic connecting rod and the lower telescopic connecting rod.

The invention has the beneficial effects that:

1. the effect of expanding outward is realized front panel and rear panel to setting up through the subassembly that warp, and structural strength is great, and stability is stronger, and can stretch out and draw back around front panel and rear panel are realized to setting up through flexible subassembly to and the setting up of push-and-pull subassembly makes the inner panel piece return inside to outer plate, give the more area of stealing light in building house through warping, and to building house outer edge can play more sunshade and hide rain region, can freely change roof form, it is more practical.

2. The solar charging panel through outer plate's setting plays solar charging's effect, and is more energy-concerving and environment-protective, and through connecting the battery, realizes the electric power storage, is being used for the power supply on roof, reduces the electric energy loss.

Drawings

FIG. 1 is a schematic perspective view of the present invention;

FIG. 2 is a schematic plan view of a deformable member of the present invention;

FIG. 3 is a cross-sectional view of a front panel and a rear panel of the present invention;

FIG. 4 is a perspective view of a support plate according to the present invention;

fig. 5 is a right side view of fig. 4.

Reference numerals: 1. building a house; 2. a front panel; 20. an outer plate; 200. rolling a groove; 201. a cylinder; 202. a push-pull plate; 21. an inner plate; 210. a roller; 3. a rear panel; 40. a servo motor; 41. a shaft sleeve; 42. a left travel bar; 420. a left moving block; 43. a right travel bar; 430. a right moving block; 44. a screw; 440. moving the sleeve; 45. a connecting rod; 46. a support plate; 460. a chute; 47. an upper telescopic connecting rod; 470. a slider; 48. a lower telescopic link.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings and examples. In which like parts are designated by like reference numerals. It should be noted that the terms "front," "back," "left," "right," "upper" and "lower" used in the following description refer to directions in the drawings, and the terms "bottom" and "top," "inner" and "outer" refer to directions toward and away from, respectively, the geometric center of a particular component.

Referring to fig. 1 to 5, the working principle of the present embodiment is as follows: when the roof needs to be extended outwards, the screw 44 is driven by the servo motor 40 to rotate forwards, the screw 44 cannot move, so that the movable sleeve 440 is screwed with the screw 44 and can move forwards, the screw 44 drives the left movable block 420 and the right movable block 430 to move outwards along the left movable rod 42 and the right movable rod 43 through the connecting rod 45, so that the front panel 2 and the rear panel 3 can be driven to extend outwards, the inner panel 21 and the outer panel 20 of the front panel 2 and the rear panel 3 can be extended forwards and backwards through the upper telescopic connecting rod 47 and the lower telescopic connecting rod 48, the front panel 2 and the rear panel 3 are driven to extend outwards, after the inner panel 21 is pulled back into the outer panel 20 through the push-pull assembly, more sunlight irradiation spaces are provided for the building house 1, the roof can be deformed at any time, and the roof is more suitable for a sunlight house and a tourist attraction.

The energy-saving movable deformable roof structure comprises a building house 1 and a deformable roof, wherein the deformable roof comprises a front panel 2 and a rear panel 3, the front panel 2 and the rear panel 3 are supported at the upper end of the building house 1 through deformation components at the lower ends of two sides, the front panel 2 and the rear panel 3 are symmetrical to each other, the deformation components are provided with two supporting ends, the front panel 2 and the rear panel 3 are respectively fixed on the supporting ends, a servo motor 40 is arranged in the deformation components, the servo motor 40 rotates to drive the supporting ends to move, the front panel 2 and the rear panel 3 both comprise an inner plate 21 and an outer plate 20, the inner plate 21 is inserted into the outer plate 20, a push-pull component is arranged in the outer plate 20, and a push-pull plate 202 of the push-pull component is fixed with the inner plate 21.

Referring to fig. 2, as a modified specific embodiment, the deformation assembly includes a servo motor 40, a screw 44, a left moving rod 42, a right moving rod 43, a moving sleeve 440, a left moving block 420 and a right moving block 430, a shaft sleeve 41 is sleeved on the front end of the servo motor 40, the screw 44 passes through a shaft hole of the shaft sleeve 41 and is connected with the servo motor 40, the shaft sleeve 41 is fixed on the servo motor 40, the shaft sleeve 41 is not in contact with the screw 44, the left moving rod 42 and the right moving rod 43 are fixed on two symmetrical ends of the shaft sleeve 41, the left moving block 420 and the right moving block 430 are respectively sleeved on the left moving rod 42 and the right moving rod 43, the moving sleeve 440 is screwed on the screw 44, the moving sleeve 440 has an internal thread groove matched with an external thread of the screw 44, the moving sleeve 440, the left moving block 420 and the right moving block 430 are synchronously moved by a connecting rod 45, the support ends of the left moving block 420 and the right moving block 430 are respectively fixed with the support plate 46, and the support plates 46 of the left moving block 420 and the right moving block 430 are respectively connected with the front panel 2 and the rear panel 3 through telescopic components.

The servo motor 40 rotates forward to drive the screw rod 44 to rotate forward, the screw rod 44 rotates forward to drive the moving sleeve 440 to move outwards, the moving sleeve 440 drives the left moving block 420 and the right moving block 430 to move outwards through the connecting rod 45, therefore, the supporting plate 46, the front panel 2 and the rear panel 3 are also driven to move outwards, and similarly, the servo motor 40 rotates backward, and the front panel 2 and the rear panel 3 move backwards to be recovered.

Referring to fig. 2, as a modified embodiment, the telescopic assembly includes an upper telescopic link 47 and a lower telescopic link 48, the telescopic head of the upper telescopic link 47 is fixed at the lower end of the inner plate 21, the telescopic head of the lower telescopic link 48 is fixed at the lower end of the outer plate 20, the upper telescopic link 47 and the lower telescopic link 48 are both located in the support plate 46, the lower telescopic link 48 is fixed in the support plate 46, and the upper telescopic link 47 is slidably connected in the support plate 46.

The upper telescopic connecting rod 47 and the lower telescopic connecting rod 48 are respectively fixed at the lower ends of the inner plate 21 and the outer plate 20 to realize outward expansion and inward contraction of the inner plate 21 and the outer plate 20 on the vertical plane of the supporting plate 46, the outer plate 20 is fixed on the supporting plate 46, and the inner plate 21 can be movably arranged in the outer plate 20 to be matched with a push-pull assembly for push-pull.

As a modified embodiment, the upper pantograph linkage 47 is fixed within the support plate 46 and the lower pantograph linkage 48 is slidably connected within the support plate 46.

The above embodiment can fix the inner plate 21, and the outer plate 20 is driven by the cylinder 201 to extend to the outer end, so as to extend to shield rain and sunlight.

Referring to fig. 4 to 5, as a modified specific embodiment, a sliding slot 460 is formed in the supporting plate 46, the sliding slot 460 is of a convex type, a sliding block 470 is fixed at the lower end of the upper telescopic link 47, and the sliding block 470 is slidably disposed in the sliding slot 460 in a matching manner.

The slide block 470 and the slide groove 460 are movably disposed on a limit basis so as to move the upper telescopic link 47.

Referring to fig. 3, as a modified embodiment, the push-pull assembly includes a cylinder 201, a head of the cylinder 201 is fixed to a push-pull plate 202, and the push-pull plate 202 is fixed to a bottom end of the inner plate 21.

The cylinder 201 drives the inner plate 21 to move, so as to realize the contraction and expansion of the inner plate 21 on the outer plate 20.

Referring to fig. 3, as a modified specific embodiment, a plurality of rollers 210 are connected to the outer ends of the two sides of the inner plate 21, rolling grooves 200 are formed in the two sides of the inner end of the outer plate 20, and the rollers 210 are fittingly arranged in the rolling grooves 200.

Through the arrangement of the roller 210 and the rolling groove 200, the inner plate 21 does not directly contact with the inner side of the outer plate 20, so that the friction force is reduced, and the cylinder 201 is more convenient to push.

Referring to fig. 1, as an embodiment of improvement, a plurality of solar charging panels are uniformly arranged on the upper end surface of the outer plate 20, and the solar charging panels are all connected to a storage battery, and the storage battery is electrically connected to the cylinder 201, the servo motor 40, the upper telescopic link 47 and the lower telescopic link 48 respectively.

Carry out solar charging through solar charging panel to and match outer plate 20 and expand the deformation through the outer of deformation subassembly, make and expand outer plate 20 in order to carry out solar charging under the condition that can not contact the sun, carry out the battery electric power storage, realize energy-concerving and environment-protective effect.

The above description is only a preferred embodiment of the present invention, and the protection scope of the present invention is not limited to the above embodiments, and all technical solutions belonging to the idea of the present invention belong to the protection scope of the present invention. It should be noted that modifications and embellishments within the scope of the invention may occur to those skilled in the art without departing from the principle of the invention, and are considered to be within the scope of the invention.

Claims

1. An energy-efficient mobile deformable roof construction comprising a building house (1) and a deformable roof, characterized in that: the deformable roof comprises a front panel (2) and a rear panel (3), wherein the front panel (2) and the rear panel (3) are supported at the upper end of a building house (1) through deformation components at the lower ends of two sides, the front panel (2) and the rear panel (3) are symmetrical to each other, the deformation components are provided with two supporting ends, the front panel (2) and the rear panel (3) are respectively fixed on the supporting ends, a servo motor (40) is arranged in the deformation components, the servo motor (40) rotates to drive the supporting ends to move, the front panel (2) and the rear panel (3) both comprise an inner plate (21) and an outer plate (20), the inner plate (21) is inserted into the outer plate (20), a push-pull component is arranged in the outer plate (20), a push-pull plate (202) of the push-pull component is fixed with the inner plate (21), and the deformation components comprise the servo motor (40), The front end of the servo motor (40) is sleeved with a shaft sleeve (41), the screw (44) penetrates through the shaft hole of the shaft sleeve (41) to be connected with the servo motor (40), the shaft sleeve (41) is fixed on the servo motor (40), the shaft sleeve (41) is not contacted with the screw (44), the left moving rod (42) and the right moving rod (43) are fixed at the two symmetrical ends of the shaft sleeve (41), the left moving rod (42) and the right moving rod (43) are respectively sleeved with the left moving block (420) and the right moving block (430), the screw (44) is screwed with the moving sleeve (440), the moving sleeve (440) is provided with an internal thread groove matched with the external thread of the screw (44), and the moving sleeve (440), the left moving block (420) and the right moving block (430) are penetrated through by a connecting rod (45) to move synchronously, the supporting ends of the left moving block (420) and the right moving block (430) are respectively fixed with a supporting plate (46), and the supporting plates (46) of the left moving block (420) and the right moving block (430) are respectively connected with the front panel (2) and the rear panel (3) through telescopic components.

2. An energy efficient, movable modified roof construction according to claim 1, characterized in that: the telescopic assembly comprises an upper telescopic connecting rod (47) and a lower telescopic connecting rod (48), a telescopic head of the upper telescopic connecting rod (47) is fixed at the lower end of the inner plate (21), a telescopic head of the lower telescopic connecting rod (48) is fixed at the lower end of the outer plate (20), the upper telescopic connecting rod (47) and the lower telescopic connecting rod (48) are both located in the supporting plate (46), the lower telescopic connecting rod (48) is fixed in the supporting plate (46), and the upper telescopic connecting rod (47) is slidably connected in the supporting plate (46).

3. An energy efficient, movable modified roof construction according to claim 2, characterized in that: be equipped with spout (460) in backup pad (46), spout (460) are protruding type, go up the lower extreme of telescopic link (47) and be fixed with slider (470), slider (470) match the slip setting in spout (460).

4. An energy efficient, movable roof construction according to claim 1 or 2 or 3, characterized in that: the push-pull assembly comprises a cylinder (201), the head of the cylinder (201) is fixed with a push-pull plate (202), and the push-pull plate (202) is fixed with the bottom end of the inner plate block (21).

5. An energy efficient, movable modified roof construction according to claim 4, characterized in that: the outer ends of the two sides of the inner plate (21) are connected with a plurality of rollers (210), the two sides of the inner end of the outer plate (20) are provided with rolling grooves (200), and the rollers (210) are arranged in the rolling grooves (200) in a matching mode.

6. An energy efficient, movable modified roof construction according to claim 4, characterized in that: the solar energy charging device is characterized in that a plurality of solar energy charging plates which are uniformly distributed are arranged on the upper end face of the outer plate (20), the solar energy charging plates are all connected with a storage battery, and the storage battery is respectively and electrically connected with the cylinder (201), the servo motor (40), the upper telescopic connecting rod (47) and the lower telescopic connecting rod (48).