CN111616035A

CN111616035A - Intelligent potted landscape water-saving irrigation system

Info

Publication number: CN111616035A
Application number: CN202010543400.2A
Authority: CN
Inventors: 高峰
Original assignee: Guangzhou Nanxinhe Technology Co ltd
Current assignee: Guangzhou Nanxinhe Technology Co ltd
Priority date: 2020-06-15
Filing date: 2020-06-15
Publication date: 2020-09-04

Abstract

The invention discloses an intelligent water-saving irrigation system for bonsais, which comprises two bases which are symmetrically distributed left and right, wherein a planting platform capable of moving up and down is arranged between the two bases, and an intelligent irrigation mechanism for watering the bonsais is also arranged in the two bases.

Description

Intelligent potted landscape water-saving irrigation system

Technical Field

The invention relates to the field of energy-saving irrigation, in particular to an intelligent bonsai water-saving irrigation system.

Background

In order to add an aesthetic effect to the environment, some landscape plants are often planted on balconies of houses, watering needs to be carried out on the landscape plants at regular time, and when the plants are watered on the balconies at high positions, water splashing can be caused to affect residents and pedestrians at lower layers.

At the present stage, general landscape plants do not have the function of automatically sensing the water shortage state, and need to be watered manually, and water splashing can be caused inevitably to influence other people when manually watering, and general landscape plant planting platforms can not accumulate rainwater, and can not reach the purpose of energy-saving irrigation.

Disclosure of Invention

The invention aims to provide an intelligent potted landscape water-saving irrigation system, which solves the problems that the automatic lifting irrigation cannot be carried out, the water storage and energy-saving irrigation cannot be carried out and the like, and increases the functions of the automatic lifting irrigation and the water storage and energy-saving irrigation.

The invention is realized by the following technical scheme.

The invention discloses an intelligent potted landscape water-saving irrigation system which comprises two bases which are symmetrically distributed left and right, wherein a planting platform capable of moving up and down is arranged between the two bases, an energy-saving water storage mechanism for storing water in rainy days and automatically replenishing water is arranged at the upper ends in the two bases, a water shortage induction mechanism for detecting whether a plant is in a water shortage state is arranged in the planting platform, and an intelligent irrigation mechanism for watering a potted plant is also arranged in the two bases; the intelligent irrigation mechanism comprises two displacement cavities which are respectively positioned in the two bases and have openings towards the planting table, a displacement block capable of moving up and down is arranged in each of the two displacement cavities, the two displacement blocks are respectively fixedly connected with the left end surface and the right end surface of the planting table, the lower end surface of each of the two displacement blocks is respectively connected with the right inner wall of the lower end of the displacement cavity, which is connected with an elastic spring on the left side, a first motor is arranged in the right inner wall of the lower end of the displacement cavity, the left end of the first motor is in power connection with a driving cavity, a rotating gear is arranged on the driving cavity, a first rack meshed with the rotating gear is fixed on the lower end surface of each of the displacement blocks, a first driven cavity with an opening towards the planting table is arranged in the middle of each of the two bases, a rotating rod is rotated on the front inner wall and the rear wall of the first driven cavity, a driving belt wheel is arranged at the, two first driven chamber upside all is equipped with the second driven chamber, it has the rotary rod to rotate on the inner wall around the second driven chamber, the rotary rod front end is equipped with driven pulleys, driven pulleys with the transmission is connected with the belt between the driving pulley, the rotary rod rear end is equipped with drive gear, two all be equipped with an opening in the second driven chamber upper inner wall to plant the flexible chamber of platform, two flexible intracavity all be equipped with one can the side-to-side movement and down the terminal surface with drive gear meshed flexible piece, two all be equipped with one in the flexible piece and water pipeline, two water pipeline is close to the one end of planting the platform all is equipped with a shower nozzle.

Furthermore, a lifting cavity is arranged at the lower side of each of the two telescopic cavities, a lifting block capable of moving up and down is arranged in each of the two lifting cavities, a push plate cavity with an upward opening is arranged in each lifting block, a push plate capable of moving up and down is arranged in each push plate cavity, two connecting springs are connected between the lower end face of each push plate and the lower inner wall of each push plate cavity, a rack is fixed on the lower end face of each push plate, a supporting spring is connected between the lower end face of each lifting block and the lower inner wall of each lifting cavity, rotating shafts are arranged on the left inner wall and the right inner wall of the lower end of each lifting cavity in a rotating mode, sector gears meshed with the racks are arranged on the two rotating shafts respectively, worm gears are arranged at the ends, far away from the planting tables, of the two displacement blocks, second motors are fixed at the ends, far away from the planting tables, and driving shafts extending into, two be equipped with initiative bevel gear on the driving shaft, two the inner wall rotates under the lift chamber and is equipped with the lower extreme and stretches into the pivot of displacement intracavity, the pivot lower extreme be equipped with can with initiative bevel gear engaged with driven bevel gear, the pivot upper end be equipped with worm wheel engaged with worm, the lift chamber upper inner wall can with watering pipeline one end intercommunication.

Furthermore, the energy-saving water storage mechanism comprises water storage cavities arranged at the upper ends of the two bases, the upper sides of the two water storage cavities are respectively provided with a water inlet cavity with an upward opening, the lower inner walls of the two water inlet cavities are respectively provided with a water inlet communicated with the water storage cavities, the left inner wall of the water storage cavity and the right inner wall of the water storage cavity on the right side are respectively provided with a drainage pipeline, the lower sides of the two water storage cavities are communicated with the lifting cavity on the same side, the two water storage cavities are respectively provided with a first floating plate capable of moving up and down, the upper inner wall of the water storage cavity is internally provided with a movable cavity with a downward opening, the movable cavity is internally provided with a movable block capable of moving up and down, an extension spring is connected between the upper end surface of the movable block and the upper inner wall of the movable cavity, the lower end surface of the movable block and the upper end surface of the, two the base upper end all is external to have one end can with the homonymy external water pipe of activity chamber intercommunication.

Further, the water shortage induction mechanism comprises a planting cavity which is positioned in the planting platform and has an upward opening, a moving cavity with a rightward opening is arranged in the left inner wall at the lower end of the planting cavity, a moving block capable of moving up and down is arranged in the moving cavity, a compression spring is connected between the lower end surface of the moving block and the lower inner wall of the moving cavity, a second floating plate positioned in the planting cavity is fixed on the right end surface of the moving block, a power-on cavity is arranged at the upper side of the moving cavity, a conductive block is fixed at the lower end in the power-on cavity, a battery block capable of moving up and down is arranged at the upper end in the power-on cavity, a pressure spring is connected between the lower end surface of the battery block and the lower inner wall of the electrifying cavity, a pull rope is connected between the lower end surface of the battery block and the upper end surface of the moving block, and electric wires are respectively electrically connected between the conductive blocks and the two second motors and between the conductive blocks and the first motors.

Furthermore, a partition board is fixed on the inner side wall of the lower end in the planting cavity, plants can be planted on the partition board, and water is filled at the lower end in the planting cavity.

The invention has the beneficial effects that: this equipment provides the planting platform of an automatic irrigation for the view plant, when sensing the water shortage state of plant, can transport the view plant downwards automatically, and water at the plant upside, effectual water of having avoided watering the eminence time can splash and influence pedestrian's problem, will water and can rise so that the plant can carry out photosynthesis with the plant is automatic after finishing again, can accumulate the rainwater at the usable equipment of rainy day, still can connect the pipeline automatically and add water when the rainwater is not enough, thereby can realize the purpose of energy-conserving irrigation.

Drawings

In order to more clearly illustrate the embodiments of the invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the invention, and it is obvious for those skilled in the art that other drawings can be obtained based on these drawings without creative efforts.

FIG. 1 is a schematic structural diagram of an embodiment of the present invention;

FIG. 2 is a schematic structural diagram at A-A in FIG. 1 according to an embodiment of the present invention;

FIG. 3 is a schematic structural diagram at B in FIG. 1 according to an embodiment of the present invention.

Detailed Description

The invention will now be described in detail with reference to fig. 1-3, wherein for ease of description the orientations described hereinafter are now defined as follows: the up, down, left, right, and front-back directions described below correspond to the up, down, left, right, and front-back directions in the projection relationship of fig. 1 itself.

Referring to the attached drawings 1-3, an intelligent bonsai water-saving irrigation system comprises two bases 10 which are symmetrically distributed left and right, a planting platform 42 which can move up and down is arranged in the middle of the two bases 10, an energy-saving water storage mechanism 76 which stores water in rainy days and automatically supplements water is arranged at the upper end in the two bases 10, a water shortage sensing mechanism 75 which detects whether a plant is in water shortage is arranged in the planting platform 42, an intelligent watering mechanism 77 which waters a potted plant is further arranged in the two bases 10, the intelligent watering mechanism 77 comprises two displacement cavities 56 which are respectively arranged in the two bases 10 and have openings towards the planting platform 42, two displacement blocks 55 which can move up and down are arranged in the displacement cavities 56, the two displacement blocks 55 are respectively and fixedly connected with the left end face and the right end face of the planting platform 42, the lower end faces of the two displacement blocks 55 are respectively and connected with the lower inner walls of the two displacement cavities 56, wherein an elastic spring 54 is arranged on the left A first motor 50 is arranged in the base, the left end of the first motor 50 is in power connection with a driving cavity 51, a rotating gear 52 is arranged on the driving cavity 51, a first rack 53 meshed with the rotating gear 52 is fixed on the lower end face of the displacement block 55, two first driven cavities 60 with openings facing the planting table 42 are arranged in the middle of the base 10, rotating rods 58 are arranged on the front and rear inner walls of the first driven cavities 60 in a rotating mode, a driving pulley 66 is arranged at the front end of each rotating rod 58, a friction wheel 59 in friction connection with the end face of the planting table 42 is arranged at the rear end of each rotating rod 58, a second driven cavity 64 is arranged on the upper sides of the two first driven cavities 60, a rotating rod 65 is arranged on the front and rear inner walls of the second driven cavities 64 in a rotating mode, a driven pulley 62 is arranged at the front end of each rotating rod 65, a belt 61 is connected between the driven pulley 62 and the driving pulley 66, and a transmission gear 63 is arranged, two be equipped with in the second driven chamber 64 the inner wall all one the opening to plant the flexible chamber 29 of platform 42, two all be equipped with in the flexible chamber 29 one can the side-to-side movement and the lower terminal surface with the flexible piece 28 of drive gear 63 meshing, two all be equipped with one in the flexible piece 28 and water the pipeline 30, two water the pipeline 30 is close to the one end of planting the platform 42 all is equipped with a shower nozzle 32.

Beneficially, a lifting cavity 72 is arranged at the lower side of each of the two telescopic cavities 29, a lifting block 33 capable of moving up and down is arranged in each of the two lifting cavities 72, a push plate cavity 22 with an upward opening is arranged in each of the lifting blocks 33, a push plate 21 capable of moving up and down is arranged in each of the push plate cavities 22, two connecting springs 20 are connected between the lower end surface of each push plate 21 and the lower inner wall of each push plate cavity 22, a rack 15 is fixed on the lower end surface of each push plate 21, a supporting spring 34 is connected between the lower end surface of each lifting block 33 and the lower inner wall of each lifting cavity 72, rotating shafts 19 are rotated on the left inner wall and the right inner wall of the lower end of each lifting cavity 72, sector gears 16 meshed with the racks 15 are respectively arranged on the two rotating shafts 19, worm gears 17 are also arranged at the ends of the two rotating shafts 19 far away from the planting platform 42, and second motors 57 are fixed at the, the two second motors 57 are respectively and dynamically connected with a driving shaft 12 extending into the displacement cavity 56, the two driving shafts 12 are provided with driving bevel gears 13, the lower inner walls of the two lifting cavities 72 are rotatably provided with rotating shafts 14, the lower ends of the rotating shafts extend into the displacement cavity 56, the lower ends of the rotating shafts 14 are provided with driven bevel gears 11 capable of being meshed with the driving bevel gears 13, the upper ends of the rotating shafts 14 are provided with worms 18 meshed with worm wheels 17, and the upper inner walls of the lifting cavities 72 can be communicated with one end of the watering pipeline 30.

Beneficially, the energy-saving water storage mechanism 76 comprises water storage cavities 26 located at the upper ends of the two bases 10, a water inlet cavity 25 with an upward opening is arranged at each of the upper sides of the two water storage cavities 26, a water inlet 24 communicated with the water storage cavity 26 is arranged at each of the lower inner walls of the two water inlet cavities 25, a water discharge pipe 73 is arranged in each of the left inner wall of the left water storage cavity 26 and the right inner wall of the right water storage cavity 26 at the left side, the lower sides of the two water storage cavities 26 are communicated with the lifting cavity 72 at the same side, a first floating plate 23 capable of moving up and down is arranged in each of the two water storage cavities 26, a movable cavity 68 with a downward opening is arranged in the upper inner wall of the water storage cavity 26, a movable block 67 capable of moving up and down is arranged in the movable cavity 68, an extension spring 69 is connected between the upper end face of the movable block 67 and the upper end face of the movable, the movable block 67 is also internally provided with a bending channel 70 with an opening at the right end and the lower end, and the upper ends of the two bases 10 are externally connected with an external water pipe 27, one end of which can be communicated with the movable cavity 68 at the same side.

Advantageously, the water shortage sensing mechanism 75 comprises a planting cavity 40 located in the planting platform 42 and opening upwards, a moving cavity 47 with a right opening is arranged in the left inner wall at the lower end of the planting cavity 40, a moving block 45 capable of moving up and down is arranged in the moving cavity 47, a compression spring 46 is connected between the lower end surface of the moving block 45 and the lower inner wall of the moving cavity 47, a second floating plate 44 positioned in the planting cavity 40 is fixed on the right end surface of the moving block 45, the upper side of the moving cavity 47 is provided with a power-on cavity 36, the lower end in the power-on cavity 36 is fixed with a conductive block 48, a battery block 37 capable of moving up and down is arranged at the upper end in the electrifying cavity 36, a pressure spring 39 is connected between the lower end surface of the battery block 37 and the lower inner wall of the electrifying cavity 36, a pull rope 38 is connected between the lower end surface of the battery block 37 and the upper end surface of the moving block 45, electric wires 35 are electrically connected between the conductive block 48 and the two second motors 57 and the first motor 50 respectively.

Advantageously, a partition plate 41 is fixed on the inner side wall of the inner lower end of the planting cavity 40, plants can be planted on the partition plate 41, and water 43 is filled in the inner lower end of the planting cavity 40.

In the initial state, the second floating plate 44 is subjected to the buoyancy of water, the pulling rope 38 is in a relaxed state, the battery block 37 is positioned on the upper side of the power-on cavity 36 under the supporting action of the pressure spring 39, the planting platform 42 is positioned on the upper side between the two bases 10, and the two telescopic blocks 28 are respectively positioned in the two telescopic cavities 29.

When the plants in the planting cavity 40 lack water, the water level of the water 43 in the planting cavity 40 is reduced to drop, the second floating plate 44 moves downwards to drive the moving block 45 to move downwards, so that the battery block 37 is pulled downwards through the pull rope 38, the battery block 37 moves downwards to be in contact with the conductive block 48 for electrifying, the first motor 50 and the two second motors 57 start to work, the first motor 50 works to drive the driving cavity 51 and the rotating gear 52 on the driving cavity 51 to rotate, the rotating gear 52 rotates to drive the first rack 53 engaged with the rotating gear 52 to move downwards, so as to drive the two displacement blocks 55 and the planting platform 42 to move downwards, the planting platform 42 moves downwards to drive the two friction wheels 59 in friction connection with the planting platform to rotate, so as to drive the rotating rod 58 and the driving belt wheel 66 on the rotating rod 58 to rotate, the driving belt wheel 66 rotates to drive the driven belt wheel 62 in transmission connection with the belt 61 to rotate, the driven belt wheel 62 rotates to drive the rotating rod 65, the transmission gear 63 rotates to drive the telescopic blocks 28 meshed with the transmission gear to move and extend one ends of the telescopic blocks to be positioned at the upper side of the planting platform 42, one ends of the two telescopic blocks 28 are positioned at the upper side of the planting platform 42, after the planting platform 42 is completely descended, the planting platform 42 is positioned at the lower side of the middle of the two bases 10, and at the moment, when plants in the planting cavity 40 are watered, water cannot splash down to cause interference to pedestrians; the two second motors 57 work to drive the driving shaft 12 to rotate, thereby driving the driving bevel gear 13 to rotate, after the planting platform 42 descends, the driving bevel gear 13 is meshed with the driven bevel gear 11, the driving bevel gear 13 rotates to drive the driven bevel gear 11 meshed therewith to rotate, the driven bevel gear 11 rotates to drive the rotating shaft 14 and the worm 18 on the rotating shaft 14 to rotate, the worm 18 rotates to drive the worm wheel 17 meshed therewith to rotate, thereby driving the rotating shaft 19 and the sector gear 16 on the rotating shaft 19 to rotate, when the sector gear 16 rotates to be meshed with the rack 15, the rack 15 moves upwards to drive the lifting block 33 and the push plate 21 to move upwards together, when the lifting block 33 moves upwards to abut against the upper inner wall of the lifting cavity 72, the rack 15 does not push the lifting block 33 to move upwards any more, but only pushes the push plate 21 to move upwards, the push plate 21 moves upwards to push the water in the push plate cavity 22 upwards into the watering pipe, finally, the water is sprayed out from the spray head 32 to water the plants in the planting cavity 40, when the sector gear 16 rotates to be disengaged from the rack 15, the lifting block 33 and the rack 15 move downwards under the action of the tension of the supporting spring 34 to reset, and at the moment, the water in the water storage cavity 26 enters the push plate cavity 22 again so as to water the plants at the next time; after watering is finished, the water level of water 43 at the lower end of the planting cavity 40 rises, the second floating plate 44 moves upwards again under the action of buoyancy of the water to reset, the battery block 37 moves upwards to reset under the action of the elastic force of the pressure spring 39 and is separated from the contact with the conductive block 48, the first motor 50 and the two second motors 57 are powered off and stop working, the two displacement blocks 55 and the planting platform 42 move upwards to reset under the action of the elastic force of the two elastic springs 54, so that a friction wheel 59 meshed with the side end face of the planting platform 42 is driven to rotate reversely, and the telescopic block 28 is driven to move to reset through mechanical transmission; when storing water in rainy days, rainwater falls into the water inlet cavity 25 and enters the water storage cavity 26 through the water inlet 24, when the water level reaches the drainage pipeline 73, redundant water can be discharged from the drainage pipeline 73, when the water storage cavity 26 is short of water, the first floating plate 23 moves downwards under the action of self gravity, so that the string 71 is tensioned, the movable block 67 moves downwards under the action of the pulling force of the string 71, at the moment, the bent channel 70 in the movable block 67 is communicated with the external water pipe 27, water in the external water pipe 27 enters the water storage cavity 26 through the bent channel 70, after the water storage in the water storage cavity 26 is finished, the first floating plate 23 moves upwards under the action of the buoyancy of the water to reset, the movable block 67 moves upwards under the action of the pulling force of the tension spring 69 to block the external water pipe 27 again, and the water adding is stopped.

The above embodiments are merely illustrative of the technical ideas and features of the present invention, and the purpose thereof is to enable those skilled in the art to understand the contents of the present invention and implement the present invention, and not to limit the protection scope of the present invention. All equivalent changes and modifications made according to the spirit of the present invention should be covered within the protection scope of the present invention.

Claims

1. The utility model provides an intelligent potted landscape water-saving irrigation system, includes the base of two bilateral symmetry distributions, its characterized in that: a planting platform capable of moving up and down is arranged between the two bases, an energy-saving water storage mechanism for storing water in rainy days and automatically replenishing water is arranged at the upper end in the two bases, a water shortage sensing mechanism for detecting whether a plant is in a water shortage state is arranged in the planting platform, and an intelligent watering mechanism for watering a potted plant is also arranged in the two bases; the intelligent irrigation mechanism comprises two displacement cavities which are respectively positioned in the two bases and have openings towards the planting table, a displacement block capable of moving up and down is arranged in each of the two displacement cavities, the two displacement blocks are respectively fixedly connected with the left end surface and the right end surface of the planting table, the lower end surface of each of the two displacement blocks is respectively connected with the right inner wall of the lower end of the displacement cavity, which is connected with an elastic spring on the left side, a first motor is arranged in the right inner wall of the lower end of the displacement cavity, the left end of the first motor is in power connection with a driving cavity, a rotating gear is arranged on the driving cavity, a first rack meshed with the rotating gear is fixed on the lower end surface of each of the displacement blocks, a first driven cavity with an opening towards the planting table is arranged in the middle of each of the two bases, a rotating rod is rotated on the front inner wall and the rear wall of the first driven cavity, a driving belt wheel is arranged at the, two first driven chamber upside all is equipped with the second driven chamber, it has the rotary rod to rotate on the inner wall around the second driven chamber, the rotary rod front end is equipped with driven pulleys, driven pulleys with the transmission is connected with the belt between the driving pulley, the rotary rod rear end is equipped with drive gear, two all be equipped with an opening in the second driven chamber upper inner wall to plant the flexible chamber of platform, two flexible intracavity all be equipped with one can the side-to-side movement and down the terminal surface with drive gear meshed flexible piece, two all be equipped with one in the flexible piece and water pipeline, two water pipeline is close to the one end of planting the platform all is equipped with a shower nozzle.

2. The intelligent bonsai water-saving irrigation system according to claim 1, wherein: a lifting cavity is arranged at the lower side of each of the two telescopic cavities, a lifting block capable of moving up and down is arranged in each of the two lifting cavities, a push plate cavity with an upward opening is arranged in each lifting block, a push plate capable of moving up and down is arranged in each push plate cavity, two connecting springs are connected between the lower end face of each push plate and the lower inner wall of each push plate cavity, a rack is fixed on the lower end face of each push plate, a supporting spring is connected between the lower end face of each lifting block and the lower inner wall of each lifting cavity, rotating shafts are arranged on the left inner wall and the right inner wall of the lower end of each lifting cavity in a rotating mode, sector gears meshed with the racks are arranged on the two rotating shafts respectively, worm gears are arranged at the ends, far away from the planting tables, of the two displacement blocks, second motors are fixed at the ends, far away from the planting tables, of the two, two be equipped with initiative bevel gear on the driving shaft, two the inner wall rotates under the lift chamber and is equipped with the lower extreme and stretches into the pivot of displacement intracavity, the pivot lower extreme be equipped with can with initiative bevel gear engaged with driven bevel gear, the pivot upper end be equipped with worm wheel engaged with worm, the lift chamber upper inner wall can with watering pipeline one end intercommunication.

3. The intelligent bonsai water-saving irrigation system according to claim 1, wherein: the energy-saving water storage mechanism comprises water storage cavities which are positioned at the upper ends of two bases, wherein the upper sides of the two water storage cavities are respectively provided with a water inlet cavity with an upward opening, the lower inner walls of the two water inlet cavities are respectively provided with a water inlet communicated with the water storage cavities, the left inner wall of the water storage cavity and the right inner wall of the water storage cavity on the right side are respectively provided with a drainage pipeline, the lower sides of the two water storage cavities are communicated with the lifting cavity on the same side, the two water storage cavities are respectively provided with a first floating plate capable of moving up and down, the upper inner wall of the water storage cavity is internally provided with a movable cavity with a downward opening, a movable block capable of moving up and down is arranged in the movable cavity, an extension spring is connected between the upper end surface of the movable block and the upper inner wall of the movable cavity, the lower end surface of the movable block and the upper end, two the base upper end all is external to have one end can with the homonymy external water pipe of activity chamber intercommunication.

4. The intelligent bonsai water-saving irrigation system according to claim 3, wherein: the water shortage induction mechanism comprises a planting cavity which is located in the planting table and has an upward opening, a moving cavity with a rightward opening is formed in the left inner wall of the lower end of the planting cavity, a moving block capable of moving up and down is arranged in the moving cavity, a compression spring is connected between the lower end face of the moving block and the lower inner wall of the moving cavity, a second floating plate located in the planting cavity is fixed to the right end face of the moving block, a power-on cavity is arranged on the upper side of the moving cavity, a conductive block is fixed to the lower end of the power-on cavity, a battery block capable of moving up and down is arranged at the upper end of the power-on cavity, a pressure spring is connected between the lower end face of the battery block and the lower inner wall of the power-on cavity, a pull rope is connected between the lower end face of the battery block and the upper end face.

5. The intelligent bonsai water-saving irrigation system according to claim 4, wherein: the planting cavity is characterized in that a partition plate is fixed on the inner side wall of the lower end of the planting cavity, plants can be planted on the partition plate, and water is filled at the lower end of the planting cavity.