The invention relates to intelligent household appliances. In particular, the invention relates to an automatically clean and dry device via ultrasonic vacuum for intelligent household umbrellas.
In the know technology, an umbrella includes ribs and a waterproof cloth that covers the ribs. Part of the ribs include a folding mechanism to reduce the volume of the umbrella. Umbrellas bring a lot of convenience to people's life; however, how to put way umbrellas after use is a problem. On one hand, rainwater falls from the umbrella to the ground, which causes the ground to be slippery. The slippery ground is dangerous to especially the elder and children. On another hand, rainwater corrodes the umbrella. Unfolding the umbrella to dry it occupies large room.
As for mechanical methods, drying, spinning, or their combination are common methods to remove the rainwater from the surface of the umbrella. However, the waterproof cloth of the existing umbrellas is generally made of combustible and deformable material such as chemical fiber. Drying may damage the waterproof cloth. And the ribs are easily to be deformed, falling off and damaged during the rotation. Although the common mechanical methods can remove rainwater from umbrellas, the methods would easily damage the umbrellas. Moreover, the methods do not clean the umbrellas. Therefore, it is desired to develop an automatically clean and dry device via ultrasonic vacuum for intelligent household umbrellas.
The technical problem to be solved is to overcome the above-mentioned deficiency by providing an automatically clean and dry device via ultrasonic vacuum for intelligent household umbrellas. The umbrella of the invention has advantages of having reasonable and simple structure, various functions, being easy to use, safe and reliable, not easily to be damaged, etc. It effectively solves the problem regarding the fact that the existing umbrella drying devices tend to damage the umbrellas.
The technical solution of the invention is to provide an automatically clean and dry device via ultrasonic vacuum for intelligent household umbrellas which includes a sleeve, a folding bracket, a sliding plate, and a rainwater collector. The sleeve includes an upper sleeve, a middle sleeve, a telescopic sleeve and a lower sleeve.
The upper sleeve and the middle sleeve are sleeved, and are engaged with each other at the sleeve place. The outside wall of the upper end of the upper sleeve is provided with an annular box and an umbrella cover. The umbrella cover is folded into an annular shape and sleeved into the annular box. The upper end of the umbrella cover is sleeved at the opening of the upper end of the upper sleeve. The inside wall of the middle sleeve is provided with an annular array consisting of a plurality of ultrasonic transducers. The ultrasonic transducers are provided with fiber brushes.
The telescopic sleeve includes a first corrugated telescopic tube, connecting flanges positioned at two ends of the first corrugated telescopic tube, and a reset spring positioned at the first corrugated telescopic tube. The connecting flanges positioned at two ends of the first corrugated telescopic tube connect to the middle sleeve and the lower sleeve, respectively. Two ends of the reset spring respectively connect to the connecting flanges at two ends of the first corrugated telescopic tube.
The top connecting flange is provided with a water-absorbing mechanism. The water-absorbing mechanism includes a water-absorbing sleeve that extends to the openings of two ends of the inside of the first corrugated telescopic tube, a plurality of cam shafts circumferentially arranged in the inside wall of the water-absorbing sleeve, a plurality of spindles, a sponge arranged at the spindles and having a concave curved structure, a connecting element that connects the spindle and the cam shaft. The connecting ends of the spindle and the cam shaft respectively extend into an inner cavity positioned at the connecting element, and are in contact with a third cushion spring in the inner cavity.
The lower end of the lower sleeve is provided with a cushion mechanism. The upper end of the lower sleeve is provided with a screen. A deflector used to guide rainwater towards a water outlet is positioned inside the lower sleeve.
The folding bracket includes a fixed bracket connected to the externals, and a movable bracket hinged to the fixed bracket. The movable bracket connects to the middle sleeve.
The sliding plate is fixed with the externals. The sliding plate is provided with a T-shaped chute. The T-shaped chute is provided with two second cushion springs. Two ends of the T-shaped chute are provided with blocks.
The rain collector includes a support plate slidably connected with the T-shaped chute, a vacuum pump positioned on the support plate, and a water box connected with the vacuum pump. The vacuum pump connects the water outlet via a second corrugated telescopic tube.
In a further example embodiment, the upper end of the upper sleeve is provided with outward revers. The inside of the upper end of the upper sleeve is provided with an infrared switch.
In a further example embodiment, the upper end of the umbrella cover is provided with an elastic belt. The elastic belt at the upper end of the below umbrella cover in the annular box is engaged with the middle portion of the above umbrella cover. The above umbrella cover and the below umbrella cover are folded together.
In a further example embodiment, the cushion mechanism includes a cushion sleeve positioned at the lower sleeve, a first cushion spring positioned in the cushion sleeve, and a cushion column extending into the cushion sleeve and being in contact with the first cushion spring.
In a further example embodiment, the movable bracket has a projection that is integrated with the movable bracket. The projection is in contact with the fixed bracket.
In a further example embodiment, the housing covers the vacuum pump and the water box, and connects with the support plate.
In a further example embodiment, a micro controller is positioned below the folding bracket. The micro controller is electrically connected to the infrared switch and the ultrasonic transducers.
In a further example embodiment, a press type switch used to control the vacuum pump is positioned above the housing. Two ends of the press type switch are electrically connected to the vacuum pump and the micro controller, respectively. The press type switch and the cushion column are positioned on the same shaft.
The technical effect of the invention is an automatically clean and dry device via ultrasonic vacuum for intelligent household umbrellas which includes a sleeve, a folding bracket, a sliding plate, and a rainwater collector. Two ends of the folding bracket connect to the sleeve and a fixed surface of the externals, respectively. The sleeve can be folded to save room when the sleeve is not used. Two ends of the sliding plate connect to the rainwater collector and a connecting surface of the externals, respectively. The rainwater collector can slide along the sliding plate to adapt to the length of the umbrella. By the combination of the ultrasonic wave and the brushes, the sleeve can shake off the rainwater from the umbrella and on other hand, the vibrated brushes clean the surface of the umbrella. The rainwater falls downstream and goes through the water-accumulating mechanism adapted to the diameter of the umbrella and the vacuum pump, such that the rainwater is collected into the water box. When the umbrella is pulled out, the umbrella cover on the sleeve automatically covers the umbrella. The device of the invention has advantages of having reasonable and simple structure, and various functions, being easy to use, safe and reliable, and not being easily damaged, etc. It effectively solves the problem regarding the fact that the existing dry devices for umbrellas easily damage the umbrellas.
The invention is illustrated by the following figures and embodiments.
The reference numbers of the figures are as follows:
1: sleeve; 11: upper sleeve; 111: annular box; 112; umbrella cover; 113: elastic belt; 12: middle sleeve; 121: ultrasonic transducer; 122: brush; 123: micro controller; 13: telescopic sleeve; 131: first corrugated telescopic tube; 132: connecting flange; 133: reset spring; 134: water-absorbing mechanism; 1341: water-absorbing sleeve; 1342: cam shaft; 1343: connecting element; 1344: spindle; 1345: sponge; 1346: inner cavity; 1347: third cushion spring; 14: lower sleeve; 141: cushion mechanism; 1411: cushion sleeve; 1412: cushion column; 1413: first cushion spring; 142: screen; 143: deflector; 144: water outlet; 145: second corrugated telescopic tube; 2: folding bracket; 21: fixed bracket; 22: movable bracket; 23: projection; 3: sliding plate; 31: T-shaped chute; 32: block; 33: second cushion spring; 4: rainwater collector; 41: support plate; 42: vacuum pump; 43: water box; 44: press type switch; 45: housing.
The invention is illustrated in accordance with figures. The figures as simplified diagrams demonstrate the basic structures of the apparatus of embodiments of the invention. Thus, the invention is not limited to the figures.
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In an example embodiment, the connecting element is made of elastic material. The connecting ends of the spindle 1344 and the cam shaft 1342 respectively extend into an inner cavity 1346 positioned at the connecting element 1343. The third cushion 1347 is not provided in the inner cavity 1346. The elasticity of the connecting element is relied on to enable the water-absorbing mechanism 134 to have the ability of adapting to the different diameters of the umbrellas.
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In an example embodiment, a roller(s) that are in contact with the vertical wall are provided on the sliding plate 3. A hydraulic lever or a pneumatic lever is provided at the bottom of the sliding plate 3. The support plate 41 is fixedly connected to the sliding plate 3.
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The automatically clean and dry device via ultrasonic vacuum for intelligent household umbrellas of the invention includes a sleeve, a folding bracket, a sliding plate, and a rainwater collector. Two ends of the folding bracket connect to the sleeve and a fixed surface of the externals, respectively. The sleeve can be folded to save room when the sleeve is not used. Two ends of the sliding plate connect to the rainwater collector and a connecting surface of the externals, respectively. The rainwater collector can slide along the sliding plate to adapt to the length of the umbrella. By the combination of the ultrasonic wave and the brushes, the sleeve can shake off the rainwater from the umbrella and on other hand, the vibrated brushes clean the surface of the umbrella. The rainwater falls downstream and goes through the water-accumulating mechanism adapted to the diameter of the umbrella and the vacuum pump, such that the rainwater is collected into the water box. When the umbrella is pulled out, the umbrella cover on the sleeve automatically covers the umbrella. The device of the invention has advantages of having reasonable and simple structure, and various functions, being easy to use, safe and reliable, and not being easily damaged, etc. It effectively solves the problem regarding the fact that the existing dry devices for umbrellas easily damage the umbrellas.
The exemplary embodiments of the present invention are thus fully described. Although the description referred to particular embodiments, it will be clear to one skilled in the art that the present invention may be practiced with variations of these specific details. Hence this invention should not be construed as limited to the embodiments set forth herein.
Number | Date | Country | Kind |
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201721160385.3 | Sep 2017 | CN | national |