CN109594802B - Safe intelligent telescopic sunshade awning - Google Patents

Abstract

The application relates to a safe intelligent telescopic sunshade awning which comprises an awning top supporting mechanism, an awning top, awning cloth, an awning top lifting driving mechanism, an awning cloth shrinkage mechanism, a controller and an environment sensor, wherein the awning top is movably arranged at the top of the awning top supporting mechanism, the awning top lifting driving mechanism is arranged behind the awning top supporting mechanism and is hinged with the rear side of the awning top, the awning cloth shrinkage mechanism is arranged on the top surface of the awning top, one side of the awning cloth is fixed on the awning top, the other side of the awning cloth is arranged on the awning cloth shrinkage mechanism, the controller and the environment sensor are respectively and fixedly arranged on the side surface of the awning top supporting mechanism, and the controller is respectively connected with the environment sensor, the awning top lifting driving mechanism and the awning cloth shrinkage mechanism through wires. The beneficial effects of the application are as follows: the awning can be controlled to change the working state according to the environmental change monitored by the environmental sensor, and the unfolding area of the awning cloth can be adjusted according to the requirement of the sunshade and rain-shielding area; when typhoons exist, the awning cloth and the awning top can be retracted, so that the sunshade canopy is prevented from being blown out by typhoons.

Description

Safe intelligent telescopic sunshade awning

Technical Field

The application relates to the field of sunshade rainsheds, in particular to a safe and intelligent telescopic sunshade rainshed.

Background

The sunshade rain shed is a sunshade rain-shielding tool for temporary sites or fixed sites, and is designed and manufactured according to different purposes. At present, a ceiling framework forming the sunshade awning generally adopts an integral structure, and the maximum shielding area of the manufactured sunshade awning is determined; meanwhile, the sunshade awning cannot change the state flexibly according to environmental changes, and hidden danger of unsafe use exists.

The application aims to solve the technical problem that the existing sunshade awning can not adjust the size and the state of the telescopic shelter according to the environment and the requirements.

Disclosure of Invention

The application aims to overcome the problems in the prior art and provide the safe intelligent telescopic sunshade awning.

In order to achieve the technical purpose and the technical effect, the application is realized by the following technical scheme: the utility model provides a flexible sunshade canopy of safe intelligence, includes roof supporting mechanism, roof, tarpaulin, roof lift actuating mechanism, tarpaulin shrink mechanism, controller, environmental sensor, roof movable mounting is at roof supporting mechanism top, roof lift actuating mechanism installs at roof supporting mechanism rear and is connected with the roof rear side is articulated, tarpaulin shrink mechanism installs the top surface at the roof, tarpaulin one side is fixed at the roof, and the tarpaulin opposite side is installed on tarpaulin shrink mechanism, controller, environmental sensor are fixed mounting respectively at roof supporting mechanism's side, the controller is connected with environmental sensor, roof lift actuating mechanism, tarpaulin shrink mechanism through the wire respectively.

The shed roof supporting mechanism comprises a plurality of stand columns, first angle adjusting guide wheel groups, second angle adjusting guide wheel groups and supporting shafts, wherein the bottom ends of each stand column are welded at the middle of a bottom plate perpendicular to the stand columns, the tops and the bottoms of two adjacent stand columns are fixedly connected through connecting plates respectively, each stand column is fixedly provided with a U-shaped supporting plate, the centers of the first angle adjusting guide wheel groups are sleeved at the middle of a hinge shaft arranged on the U-shaped supporting plate, the tops of the stand columns positioned at the two sides of the shed roof supporting mechanism are respectively provided with an L-shaped supporting plate, the two ends of each supporting shaft are respectively fixedly arranged on the two L-shaped supporting plates, a shaft hole in the center of each second angle adjusting guide wheel group is sleeved on the supporting shafts, the second angle adjusting guide wheel groups are positioned above the corresponding first angle adjusting guide wheel groups, and each second angle adjusting guide wheel group is formed by two pairs of guide wheels rotatably arranged at two ends of a kidney-shaped plate.

The shed roof lifting driving mechanism comprises a speed reducing motor, a driving gear A, a driven gear A, a screw rod, a guide rod, a lower supporting plate, an upper movable plate, a guide wheel and a connecting rod, wherein the lower supporting plate is fixedly arranged at the bottom of the back of the shed roof supporting mechanism, the speed reducing motor is fixed on the lower supporting plate, the top of the screw rod is arranged at the top of the back of the shed roof supporting mechanism through a bearing seat, the bottom of the screw rod is arranged on the lower supporting plate through a bearing seat, the driving gear A sleeved on a power output shaft of the speed reducing motor is meshed with the driven gear A sleeved at the bottom of the screw rod, the screw rod is in threaded connection with a screw hole formed in the upper movable plate, the bottoms of the guide wheel and the connecting rod are hinged on a guide wheel mounting plate on the front of the upper movable plate through a hinge shaft, and the guide wheel rolls up and down in a guide rail arranged on the back of a stand column; the bottom end fixed mounting of guide bar is in the bottom suspension fagging, the top cover of guide bar is in installing in the bearing frame at shed roof supporting mechanism back top, the guide bar cover is in the guiding hole of seting up on last fly leaf, gear motor passes through the wire and is connected with the controller.

The shed roof comprises a plurality of supporting beams and a cross rod, the second angle adjusting guide wheel set is arranged in a strip-shaped roller groove arranged in the middle of the supporting beams along the length direction of the supporting beams in a rolling mode, the bottom surface of the supporting beams rolls on the first angle adjusting guide wheel set, a pair of semi-cylindrical connecting blocks are respectively arranged at two ends of the supporting beams, the top of each connecting rod is hinged to a pair of connecting blocks located at the rear side of the supporting beam above the connecting rods through a hinge shaft, and the cross rod connects the connecting blocks located at the front sides of all the supporting beams in series.

The awning cloth shrinkage mechanism comprises a double-headed motor, a driving shaft, driving gears B, driven shafts and chains, wherein the double-headed motor is fixedly installed on a supporting beam positioned on one side of a shed roof, two ends of the driven shafts are respectively sleeved in bearing seats positioned on the supporting beam positioned on the other side of the shed roof, two ends of a power output shaft of the double-headed motor are respectively connected with one driving shaft through a coupling, one end, far away from the double-headed motor, of each driving shaft is sleeved in the bearing seat on the supporting beam provided with the double-headed motor, at least one driving gear B is sleeved on each driving shaft, at least two driven gears B are sleeved on the driven shafts, and the chains are simultaneously meshed with the driving gears B and the driven gears B positioned on the same transverse direction, and the double-headed motor is connected with a controller through wires.

The awning cloth comprises a foldable awning cloth body and round rods fixedly connected to the crease at the bottom of the awning cloth body, wherein the round rods on one side of the awning cloth are sleeved in a plurality of round tubes A fixed on a supporting beam provided with a double-head motor, and the round rods on the other side of the awning cloth are sleeved in round tubes B fixed on the top end of a chain.

The environment sensor comprises a wind speed sensor, a rainwater sensor and an illumination sensor, wherein the controller comprises a programmable logic controller, a speed reducing motor driver, a double-end motor driver and a touch screen, the programmable logic controller is connected with the wind speed sensor, the rainwater sensor, the illumination sensor, the speed reducing motor driver, the double-end motor driver and the touch screen through wires respectively, the speed reducing motor driver is connected with the speed reducing motor through wires, and the double-end motor driver is connected with the double-end motor through wires.

The beneficial effects of the application are as follows: the awning can be controlled to change the working state according to the environmental change monitored by the environmental sensor, and the unfolding area of the awning cloth can be adjusted according to the requirement of the sunshade and rain-shielding area; when typhoons exist, the awning cloth and the awning top can be retracted, so that the sunshade canopy is prevented from being blown out by typhoons.

Drawings

The accompanying drawings, which are included to provide a further understanding of the application and are incorporated in and constitute a part of this specification, illustrate embodiments of the application and together with the description serve to explain the application and do not constitute a limitation on the application. In the drawings:

FIG. 1 is a schematic view of a sunshade canopy according to an embodiment of the present application in a first view angle;

FIG. 2 is a schematic view of a sunshade canopy according to an embodiment of the present application in a second view angle;

FIG. 3 is a schematic view of a awning in an unfolded state, with the awning cloth body removed;

FIG. 4 is a schematic view of a canopy support mechanism according to an embodiment of the present application;

FIG. 5 is a schematic view of a first angle adjustment guide wheel set and a second angle adjustment guide wheel set according to an embodiment of the present application;

FIG. 6 is a schematic view of a canopy lifting drive mechanism in accordance with an embodiment of the present application;

FIG. 7 is a schematic view of a roof according to an embodiment of the present application;

FIG. 8 is a schematic view of a tarpaulin contraction mechanism according to the embodiment of the present application;

fig. 9 is a schematic structural view of a tarpaulin in according to an embodiment of the present application.

Detailed Description

The application will be described in detail below with reference to the drawings in combination with embodiments.

As shown in fig. 1 to 9, a safe and intelligent telescopic sunshade awning comprises a awning supporting mechanism 1, an awning lifting driving mechanism 2, an awning 3, an awning cloth shrinking mechanism 4, an awning 5, a controller 6 and an environment sensor, wherein the awning 3 is movably mounted at the top of the awning supporting mechanism 1, the awning lifting driving mechanism 2 is mounted at the rear of the awning supporting mechanism 1 and is hinged with the rear side of the awning 3, the awning shrinking mechanism 4 is mounted on the top surface of the awning 3, one side of the awning 5 is fixed on the awning 3, the other side of the awning 5 is mounted on the awning shrinking mechanism 4, the controller 6 and the environment sensor are respectively and fixedly mounted on the side surfaces of the awning supporting mechanism 1, and the controller 6 is respectively connected with the environment sensor, the awning lifting driving mechanism 2 and the awning shrinking mechanism 4 through wires.

The shed roof supporting mechanism 1 comprises three upright posts 103, a first angle adjusting guide wheel group 107, a second angle adjusting guide wheel group 108 and a supporting shaft 110, wherein the bottom end of each upright post 103 is welded at the middle part of a bottom plate 101 perpendicular to the upright posts, the tops and bottoms of two adjacent upright posts 103 are fixedly connected through connecting plates 104 respectively, the top end of each upright post 103 is fixedly provided with a U-shaped supporting plate 105, the center of each first angle adjusting guide wheel group 107 is sleeved at the middle part of a hinging shaft 106 arranged on the U-shaped supporting plate 105, the tops of the upright posts 103 positioned on two sides of the shed roof supporting mechanism 1 are respectively provided with an L-shaped supporting plate 109, two ends of each supporting shaft 110 are respectively fixedly arranged on the two L-shaped supporting plates 109, a shaft hole arranged at the center of the second angle adjusting guide wheel group 108 is sleeved on the supporting shaft 110, the second angle adjusting guide wheel group 108 is positioned above the corresponding first angle adjusting guide wheel group 107, and the first angle adjusting guide wheel group 107 and the second angle adjusting guide wheel group 108 are respectively formed by two pairs of guide wheels 112 rotatably arranged at two ends of a round template 111.

The shed roof lifting driving mechanism 2 comprises a speed reducing motor 202, a driving gear A203, a driven gear A204, a screw rod 205, a guide rod 211, a lower supporting plate 201, an upper movable plate 206, a guide wheel 208 and a connecting rod 210, wherein the lower supporting plate 201 is fixedly arranged at the bottom of the back of the shed roof supporting mechanism 1, the speed reducing motor 202 is fixed on the lower supporting plate 201, the top of the screw rod 205 is arranged at the top of the back of the shed roof supporting mechanism 1 through a bearing seat 207, the bottom of the screw rod 205 is arranged on the lower supporting plate 201 through the bearing seat 207, the driving gear A203 sleeved on a power output shaft of the speed reducing motor 202 is meshed with the driven gear A204 sleeved at the bottom of the screw rod 205, the screw rod 205 is in threaded connection with a screw hole formed in the upper movable plate 206, the guide wheel 208 and the bottom of the connecting rod 210 are hinged on a guide wheel mounting plate 209 arranged at the front of the upper movable plate 206 through a hinge shaft 212, and the guide wheel 208 rolls up and down in a guide rail 102 arranged at the back of the upright post 103; the bottom end of the guide rod 211 is fixedly arranged on the lower supporting plate 201, the top of the guide rod 211 is sleeved in a bearing seat 207 arranged on the top of the back surface of the shed roof supporting mechanism 1, the guide rod 211 is sleeved in a guide hole formed in the upper movable plate 206, and the gear motor 202 is connected with the controller 6 through a wire.

The shed roof 3 comprises three supporting beams 301 and a cross rod 305, wherein the second angle adjusting guide wheel set 108 is arranged in a strip-shaped roller groove 302 arranged in the middle of the supporting beams 301 along the length direction of the supporting beams, the bottom surface of the supporting beams 301 rolls on the first angle adjusting guide wheel set 107, two ends of the supporting beams 301 are respectively provided with a pair of semi-cylindrical connecting blocks 303, the top of each connecting rod 210 is hinged with the pair of connecting blocks 303 positioned on the rear side of the supporting beam 301 above the connecting blocks through a hinge shaft 304, and the cross rod 305 connects the connecting blocks 303 positioned on the front sides of all the supporting beams 301 in series.

The awning cloth shrinkage mechanism 4 comprises a double-headed motor 401, a driving shaft 402, a driving gear B404, a driven gear B406, a driven shaft 405 and a chain 407, wherein the double-headed motor 401 is fixedly arranged on a supporting beam 301 positioned on one side of a shed roof 3, two ends of the driven shaft 405 are respectively sleeved in bearing seats 408 positioned on the supporting beam 301 positioned on the other side of the shed roof 3, two power output shafts of the double-headed motor 401 are respectively connected with the driving shaft 402 through a coupler 403, one end, far away from the double-headed motor 401, of the driving shaft 403 is sleeved in the bearing seats 408 on the supporting beam 301 provided with the double-headed motor 401, two driving gears B404 are sleeved on each driving shaft 402, four driven gears B406 are sleeved on the driven shaft 405, the chain 407 is meshed with the driving gear B404 and the driven gear B406 positioned on the same transverse direction, and the double-headed motor 401 is connected with the controller 6 through wires.

The awning cloth 5 comprises a folding awning cloth body 501 and round rods 502 fixedly connected at folds at the bottom of the awning cloth body 501, wherein the round rods 502 positioned at one side of the awning cloth 5 are sleeved in four round tubes A503 fixed on the supporting beam 301 provided with the double-headed motor 401, and the round rods 502 positioned at the other side of the awning cloth 5 are sleeved in round tubes B409 fixed at the top end of the chain 407.

The environment sensor comprises a wind speed sensor 7, a rainwater sensor 8 and an illumination sensor 9, the controller 6 comprises a programmable logic controller, a gear motor driver, a double-headed motor driver and a touch screen 10, the programmable logic controller is respectively connected with the wind speed sensor 7, the rainwater sensor 8, the illumination sensor 9, the gear motor driver, the double-headed motor driver and the touch screen 10 through wires, the gear motor driver is connected with the gear motor 202 through wires, and the double-headed motor driver is connected with the double-headed motor 401 through wires.

The working process comprises the following steps: when the rain sensor monitors rain or the illumination sensor monitors that the illumination intensity is high, a signal is sent to the programmable logic controller, after the programmable logic controller receives the signal, the speed reducing motor driver is controlled to drive the speed reducing motor to rotate forward according to an edited control program, so that the screw rod is reversely rotated to drive the upper movable plate to move upwards to push the shed roof upwards until the shed roof is covered above the shed roof supporting mechanism, and then the programmable logic controller controls the double-headed motor driver to drive the double-headed motor to rotate forward to enable the chain to pull the awning cloth to be unfolded; when the wind speed sensor detects typhoon or the rainwater sensor detects that the wind stops raining or the illumination sensor detects that the illumination intensity is small, a signal is sent to the programmable logic controller, the programmable logic controller controls the double-headed motor to drive the double-headed motor to rotate reversely, so that the chains pull the tarpaulin to fold, the programmable logic controller controls the gear motor to drive the gear motor to rotate reversely, so that the screw rod rotates positively to drive the upper movable plate to move downwards to pull the shed roof downwards until the shed roof is positioned behind the shed roof supporting mechanism.

The foregoing has shown and described the basic principles, principal features and advantages of the application. It will be understood by those skilled in the art that the present application is not limited to the embodiments described above, and that the above embodiments and descriptions are merely illustrative of the principles of the present application, and various changes and modifications may be made without departing from the spirit and scope of the application, which is defined in the appended claims.

Claims (5)

1. A safe intelligent telescopic sunshade awning is characterized in that: the greenhouse comprises a greenhouse supporting mechanism, a greenhouse top, awning cloth, a greenhouse top lifting driving mechanism, an awning cloth shrinkage mechanism, a controller and an environment sensor, wherein the greenhouse top is movably arranged at the top of the greenhouse top supporting mechanism, the greenhouse top lifting driving mechanism is arranged at the rear of the greenhouse top supporting mechanism and is hinged with the rear side of the greenhouse top, the awning cloth shrinkage mechanism is arranged on the top surface of the greenhouse top, one side of the awning cloth is fixed on the greenhouse top, the other side of the awning cloth is arranged on the awning cloth shrinkage mechanism, the controller and the environment sensor are respectively and fixedly arranged on the side surface of the greenhouse top supporting mechanism, and the controller is respectively connected with the environment sensor, the greenhouse top lifting driving mechanism and the awning cloth shrinkage mechanism through wires;

the shed roof supporting mechanism comprises a plurality of upright posts, a first angle adjusting guide wheel group, a second angle adjusting guide wheel group and supporting shafts, wherein the bottom ends of each upright post are welded at the middle part of a bottom plate vertical to the upright posts, the tops and the bottoms of two adjacent upright posts are fixedly connected through connecting plates respectively, a U-shaped supporting plate is fixedly arranged at the top end of each upright post, the center of the first angle adjusting guide wheel group is sleeved at the middle part of a hinging shaft arranged on the U-shaped supporting plate, the tops of the upright posts positioned at the two sides of the shed roof supporting mechanism are respectively provided with an L-shaped supporting plate, the two ends of each supporting shaft are respectively fixedly arranged on the two L-shaped supporting plates, a shaft hole arranged at the center of the second angle adjusting guide wheel group is sleeved on the supporting shafts, and the second angle adjusting guide wheel group is positioned above the corresponding first angle adjusting guide wheel group;

the shed roof lifting driving mechanism comprises a speed reducing motor, a driving gear A, a driven gear A, a screw rod, a guide rod, a lower supporting plate, an upper movable plate, a guide wheel and a connecting rod, wherein the lower supporting plate is fixedly arranged at the bottom of the back of the shed roof supporting mechanism, the speed reducing motor is fixed on the lower supporting plate, the top of the screw rod is arranged at the top of the back of the shed roof supporting mechanism through a bearing seat, the bottom of the screw rod is arranged on the lower supporting plate through a bearing seat, the driving gear A sleeved on a power output shaft of the speed reducing motor is meshed with the driven gear A sleeved at the bottom of the screw rod, the screw rod is in threaded connection with a screw hole formed in the upper movable plate, the bottoms of the guide wheel and the connecting rod are hinged on a guide wheel mounting plate on the front of the upper movable plate through a hinge shaft, and the guide wheel rolls up and down in a guide rail arranged on the back of the upright post; the bottom end of the guide rod is fixedly arranged on the lower supporting plate, the top of the guide rod is sleeved in a bearing seat arranged at the top of the back surface of the shed roof supporting mechanism, and the guide rod is sleeved in a guide hole formed in the upper movable plate;

the shed roof comprises a plurality of supporting beams and a cross rod, wherein the second angle adjusting guide wheel set is arranged in a strip-shaped roller groove arranged in the middle of the supporting beams along the length direction of the supporting beams in a rolling mode, the bottom surface of the supporting beams rolls on the first angle adjusting guide wheel set, a pair of semi-cylindrical connecting blocks are respectively arranged at two ends of the supporting beams, the top of each connecting rod is hinged with a pair of connecting blocks positioned at the rear side of the supporting beam above the connecting blocks through a hinge shaft, and the cross rod connects the connecting blocks positioned at the front sides of all the supporting beams in series;

the awning cloth shrinkage mechanism comprises a double-headed motor, a driving shaft, a driving gear B, driven gears B, driven shafts and chains, wherein the double-headed motor is fixedly arranged on a supporting beam positioned on one side of a shed roof, two ends of the driven shafts are respectively sleeved in bearing seats positioned on the supporting beam positioned on the other side of the shed roof, two ends of a power output shaft of the double-headed motor are respectively connected with one driving shaft through a coupling, one end, far away from the double-headed motor, of each driving shaft is sleeved in the bearing seat on the supporting beam provided with the double-headed motor, at least one driving gear B is sleeved on each driving shaft, at least two driven gears B are sleeved on the driven shafts, and the chains are simultaneously meshed with the driving gears B and the driven gears B positioned in the same transverse direction.

2. The safety intelligent telescopic awning as claimed in claim 1, wherein: the first angle adjusting guide wheel set and the second angle adjusting guide wheel set are composed of two pairs of guide wheels rotatably arranged at two ends of the kidney-shaped plate.

3. The safety intelligent telescopic awning as claimed in claim 2, wherein: the double-headed motor is connected with the controller through a wire.

4. A safety intelligent telescopic awning as claimed in claim 3, characterised in that: the awning cloth comprises a foldable awning cloth body and round rods fixedly connected to the crease at the bottom of the awning cloth body, wherein the round rods on one side of the awning cloth are sleeved in a plurality of round tubes A fixed on a supporting beam provided with a double-head motor, and the round rods on the other side of the awning cloth are sleeved in round tubes B fixed on the top end of a chain.

5. The safety intelligent telescopic awning as claimed in claim 4, wherein: the environment sensor comprises a wind speed sensor, a rainwater sensor and an illumination sensor, wherein the controller comprises a programmable logic controller, a speed reducing motor driver, a double-end motor driver and a touch screen, the programmable logic controller is connected with the wind speed sensor, the rainwater sensor, the illumination sensor, the speed reducing motor driver, the double-end motor driver and the touch screen through wires respectively, the speed reducing motor driver is connected with the speed reducing motor through wires, and the double-end motor driver is connected with the double-end motor through wires.