CN114568183B - Indoor cultivation regulation and control economizer of national orchid tissue culture seedling - Google Patents

Abstract

The invention discloses an indoor cultivation, regulation and energy-saving device for tissue culture seedlings of Chinese orchid, which comprises: the device comprises a rack, a water storage tank, a fixed shaft, a rotating device, a fixed disc, a sleeve shaft, a lifting device and a cultivation device, wherein the rack bears working equipment, and the bottom of the rack is provided with a roller; the water storage tank is fixed on the frame; two ends of the fixed shaft are fixed on the rack, and the middle part of the fixed shaft is positioned above the water storage tank; a plurality of groups of rotating devices are linearly distributed and fixed on the fixed shaft; two fixed disks are symmetrically distributed, and the centers of the two fixed disks are fixed on the fixed shaft; the sleeve shaft is fixed on the fixed shaft and positioned between the fixed disks; a plurality of groups of lifting devices are annularly distributed and are in sliding connection with the outer wall of the sleeve shaft; the cultivation device can be rotationally fixed between the lifting devices. Compared with the prior art, the single cultivation pot is subjected to pot soaking and watering through the matching of the lifting device and the rotating device, so that water can be supplemented as required, and the cultivation effect of tissue culture seedlings is improved.

Description

Indoor cultivation regulation and control economizer of national orchid tissue culture seedling

Technical Field

The invention relates to the technical field of plant cultivation, in particular to an indoor cultivation regulation and energy-saving device for tissue culture seedlings of Chinese orchid.

Background

The Chinese orchid tissue culture seedling needs certain sunlight, temperature, humidity and circulating air for growth, and the method is particularly important for the tissue culture seedling. The irrigation and humidification mode of a common cymbidium tissue culture seedling constant-temperature culture device is single, the humidity control difficulty is high, water supplementing and humidification are difficult to carry out according to the actual growth condition of each orchid, unified irrigation and humidification are carried out, individual tissue culture seedlings are easy to generate, too much or too little water is obtained, the growth of the tissue culture seedlings is affected, and the culture effect of the cymbidium tissue culture seedlings is difficult to guarantee. Therefore, there is a need to provide an indoor cultivation, regulation and energy-saving device for tissue culture seedlings of cymbidium sinense to solve the problems in the background art.

Disclosure of Invention

In order to achieve the purpose, the invention provides the following technical scheme: an indoor cultivation regulation and energy-saving device for tissue culture seedlings of Chinese orchid comprises:

the rack bears the working equipment, and the bottom of the rack is provided with the roller, so that the movement of the whole device is convenient;

the water storage tank is fixed on the rack, stores irrigation water and is provided with a water changing device;

the two ends of the fixed shaft are fixed on the rack, and the middle part of the fixed shaft is positioned above the water storage tank;

the rotating devices are linearly distributed and provided with a plurality of groups and are fixed on the fixed shaft, and each group of rotating devices are fixedly connected with each other;

two fixed disks are symmetrically distributed and the centers of the two fixed disks are fixed on the fixed shaft;

the sleeve shaft is fixed on the fixed shaft and positioned between the fixed disks;

a plurality of groups of lifting devices are distributed in an annular manner and are connected with the outer wall of the sleeve shaft in a sliding manner;

the cultivation device can be rotationally fixed between the lifting devices.

Further, preferably, the rotating device includes:

the double-shaft motor is fixed inside the fixed shaft and driven by electric power;

the planet wheel, the symmetric distribution is provided with two, respectively with biax motor both sides rotatable coupling, carries out power transmission under biax motor's drive.

Further, preferably, the planetary gear includes:

the rotating shaft is rotatably connected with the double-shaft motor and is driven by the double-shaft motor to rotate;

the center of the sun gear is fixedly connected with the rotating shaft and rotates along with the rotating shaft;

a plurality of planet pinions which are annularly distributed, are meshed with the sun gear, and revolve around the sun gear while rotating under the driving of the sun gear;

the outer ring of the gear ring is fixed on the inner wall of the sleeve shaft, and the inner ring of the gear ring is meshed with the planet pinion to assist the planet pinion to revolve around the sun gear;

the transmission devices are annularly distributed and are in electromagnetic connection with the planet pinions, each group of transmission devices independently operate under the control of electric power, and when the transmission devices are electrified, the transmission devices and the planet pinions synchronously rotate; when power is cut off, the transmission device and the planet pinion are in a slipping state, the planet pinion independently rotates, and the transmission device revolves along with the planet pinion.

Further, preferably, the planet pinion penetrates through the fixed shaft to connect the sun gear and the gear ring, when the planet pinion revolves around the sun gear, the planet pinion is not limited by the fixed shaft, the transmission device penetrates through the fixed shaft and the sleeve shaft and is slidably connected with the lifting device, and the transmission device drives the lifting device to revolve along with the planet pinion.

Further, preferably, the transmission device includes:

the driven gear is electromagnetically connected with the planet pinion, when the power is on, the driven gear rotates along with the planet pinion synchronously, when the power is off, the driven gear and the planet pinion are in a slipping state, and the driven gear always revolves along with the planet pinion;

the rack is meshed with the driven gear, when the driven gear rotates clockwise, the rack is driven to move towards the center direction of the sun gear, and when the driven gear rotates anticlockwise, the rack is driven to move outwards;

the connector is fixed at one end, far away from the driven gear, of the rack and is in slidable connection with the lifting device, and when the rack moves, the connector is driven to move on the lifting device.

Further, as preferred, every group transmission all is not in the coplanar, when a plurality of driven gear clockwise turned, drives many racks and removes to sun gear central direction, avoids colliding each other and leads to the card to die.

Further, as preferred, the sleeve shaft is fixed between the fixed disks and fixedly connected with the fixed disks, a plurality of annular holes corresponding to the racks are formed in the sleeve shaft, and the racks penetrate through the annular holes to drive the lifting device to rotate on the sleeve shaft.

Further, preferably, the lifting device includes:

the slide ways are provided with a plurality of groups, correspond to the transmission devices, can be fixed on the outer wall of the sleeve shaft in a sliding way, and rotate around the outer wall of the sleeve shaft under the driving of the planet pinions;

the slider, slidable fixes on the slide, with connector fixed connection, when driven gear clockwise rotation, the slider removes to sleeve axle place one end on the slide, and then drives cultivation device and remove to the center, and when driven gear anticlockwise rotation, the slider removes to keeping away from sleeve axle place one end on the slide, and then drives cultivation device and remove to the outside.

Further, as the optimization, the length of the slide way is smaller than the shortest distance from the sleeve shaft to the water storage tank, when the planetary pinion drives the transmission device to revolve, the lifting device and the cultivation device are synchronously driven to revolve, and the length of the slide way influences whether the cultivation device can smoothly enter the water storage tank to irrigate.

Further, preferably, the cultivation apparatus includes:

the two ends of the balance plate are rotatably connected with the sliding block, the middle part of the balance plate is provided with a cultivation hole and a humidity monitoring device, and the cultivation device is always kept in a horizontal state when the lifting device performs circular motion under the action of the balance plate;

the cultivation pot is fixed on the cultivation hole of the balance plate, and the humidity monitoring device monitors and feeds back whether watering is needed or not.

Compared with the prior art, the invention has the beneficial effects that:

according to the invention, the rotating device is arranged to drive the cultivation pot to do circular motion, so that surrounding air is driven to flow, the air quality is improved, and meanwhile, the lifting device is matched with the water storage tank to perform pot soaking and watering on the tissue culture seedlings.

According to the invention, the transmission device is electromagnetically connected with the planet wheel, the lifting device is controlled to lift under the action of electric power, each group of transmission devices can adjust the position of each tissue culture seedling through independent control, so that the tissue culture seedlings needing watering can be watered accurately, a better growth environment is provided for the tissue culture seedlings, and water resources are saved.

Drawings

FIG. 1 is a schematic view of the overall structure of an indoor cultivation, regulation and energy-saving device for tissue culture seedlings of cymbidium;

FIG. 2 is a schematic view of a structure of a rotating device in an indoor cultivation, regulation and energy-saving device for tissue culture seedlings of Chinese orchid;

FIG. 3 is a schematic view of the internal structure of a planetary gear in an energy-saving device for indoor cultivation and regulation of tissue culture seedlings of cymbidium;

FIG. 4 is a schematic structural view of a lifting device in an indoor cultivation, regulation and energy-saving device for tissue culture seedlings of cymbidium;

in the figure: 1. a frame; 2. a water storage tank; 3. a fixed shaft; 4. a rotating device; 5. fixing the disc; 6. a sleeve shaft; 7. a lifting device; 8. a cultivation device; 41. a double-shaft motor; 42. a planet wheel; 71. a slideway; 72. a slider; 81. a balance plate; 82. cultivating pots; 421. a rotating shaft; 422. a sun gear; 423. a planet pinion gear; 424. a ring gear; 425. a transmission device; 4251. a driven gear; 4252. a rack; 4253. a connecting head.

Detailed Description

Referring to fig. 1 to 4, in an embodiment of the present invention, an indoor cultivation regulation and energy saving device for tissue culture seedlings of cymbidium includes:

the rack 1 bears working equipment, and the bottom of the rack is provided with a roller, so that the movement of the whole device is facilitated;

the water storage tank 2 is fixed on the frame 1, stores irrigation water and is provided with a water changing device;

the two ends of the fixed shaft 3 are fixed on the frame 1, and the middle part of the fixed shaft is positioned above the water storage tank 2;

the rotating devices 4 are linearly distributed and provided with a plurality of groups and are fixed on the fixed shaft 3, and each group of rotating devices 4 are fixedly connected;

two fixed disks 5 are symmetrically distributed, and the centers of the two fixed disks are fixed on the fixed shaft 3;

the sleeve shaft 6 is fixed on the fixed shaft 3 and positioned between the fixed disks 5;

a plurality of groups of lifting devices 7 are distributed annularly and are connected with the outer wall of the sleeve shaft 6 in a sliding way;

and the cultivation device 8 can be rotatably fixed between the lifting devices 7.

In this embodiment, the rotating device 4 includes:

a double-shaft motor 41 fixed inside the fixed shaft 3 and driven by electric power;

the planet wheels 42 are symmetrically distributed and are respectively rotatably connected with two sides of the double-shaft motor 41, and power transmission is carried out under the driving of the double-shaft motor 41.

In this embodiment, the planetary gear 42 includes:

a rotating shaft 421 rotatably connected to the dual-shaft motor 41 and driven by the dual-shaft motor 41 to rotate;

a sun gear 422, the center of which is fixedly connected with the rotating shaft 421 and rotates along with the rotating shaft 421;

a plurality of planetary pinions 423 annularly distributed, engaged with the sun gear 422, and revolving around the sun gear 422 while rotating under the drive of the sun gear 422;

the outer ring of the gear ring 424 is fixed on the inner wall of the sleeve shaft 6, and the inner ring of the gear ring is meshed with the planet pinion 423 to assist the planet pinion 423 to revolve around the sun gear 422;

the transmission devices 425 are annularly distributed and provided with a plurality of groups and are in electromagnetic connection with the planet pinions 423, each group of transmission devices 425 independently operate under the control of electric power, and when the transmission devices 425 and the planet pinions 423 rotate synchronously; when the power is cut off, the gear 425 and the pinion gear 423 are in a slipping state, the pinion gear 423 rotates independently, and the gear 425 revolves following the pinion gear 423.

In this embodiment, the pinion gear 423 passes through the fixed shaft 3 to connect the sun gear 422 and the ring gear 424, the pinion gear 423 is not limited by the fixed shaft 3 when revolving around the sun gear 422, the transmission device 425 passes through the fixed shaft 3 and the sleeve shaft 6 to be slidably connected with the lifting device 7, and the transmission device 425 drives the lifting device 7 to revolve along with the pinion gear 423.

In this embodiment, the actuator 425 includes:

a driven gear 4251 electromagnetically connected to the pinion gear 423, wherein when the power is turned on, the driven gear 4251 rotates synchronously with the pinion gear 423, and when the power is turned off, the driven gear 4251 and the pinion gear 423 are in a slip state, and the driven gear 4251 revolves around the pinion gear 423 at all times;

a rack 4252 engaged with the driven gear 4251, and driving the rack 4252 to move toward the center of the sun gear 422 when the driven gear 4251 rotates clockwise, and driving the rack 4252 to move outward when the driven gear 4251 rotates counterclockwise;

the connector 4253 is fixed at one end of the rack 4252, which is far away from the driven gear 4251, and is in slidable connection with the lifting device 7, and when the rack 4252 moves, the connector 4253 is driven to move on the lifting device 7.

In this embodiment, each group of the transmission devices 425 is not located on the same plane, and when the plurality of driven gears 4251 rotate clockwise, the plurality of racks 4252 are driven to move towards the center of the sun gear 422, so as to avoid being jammed due to mutual collision.

In this embodiment, the sleeve shaft 6 is fixed between the fixed disks 5 and fixedly connected to the fixed disks 5, a plurality of annular holes corresponding to the racks 4252 are formed in the sleeve shaft 6, and the racks 4252 pass through the annular holes to drive the lifting device 7 to rotate on the sleeve shaft 6.

In this embodiment, the lifting device 7 includes:

the slide rails 71 are provided with a plurality of groups, correspond to the transmission devices 425, can be fixed on the outer wall of the sleeve shaft 6 in a sliding manner, and rotate around the outer wall of the sleeve shaft 6 under the driving of the planet pinions 423;

the sliding block 72 is slidably fixed on the sliding rail 71 and fixedly connected with the connecting head 4253, when the driven gear 4251 rotates clockwise, the sliding block 72 moves towards one end where the sleeve shaft 6 is located on the sliding rail 71 to drive the cultivation device 8 to move towards the center, and when the driven gear 4251 rotates anticlockwise, the sliding block 72 moves towards one end where the sleeve shaft 6 is located on the sliding rail 71 to drive the cultivation device 8 to move outwards.

In this embodiment, the length of the chute 71 is smaller than the shortest distance from the sleeve shaft 6 to the water storage tank 2, when the planetary pinion 423 drives the transmission device 425 to revolve, the lifting device 7 and the cultivation device 8 are synchronously driven to revolve, and the length of the chute 71 influences whether the cultivation device 8 can smoothly enter the water storage tank 2 for irrigation.

In this embodiment, the cultivation device 8 includes:

the two ends of the balance plate 81 are rotatably connected with the sliding block 72, the middle part of the balance plate is provided with a cultivation hole and a humidity monitoring device, and the cultivation device 8 is always kept in a horizontal state when the lifting device 7 performs circular motion under the action of the balance plate 81;

and the cultivation pot 82 is fixed on the cultivation hole of the balance plate 81, and is monitored and fed back by a humidity monitoring device to judge whether watering is needed.

In specific implementation, the tissue culture seedlings are planted in the culture pots 82 and fixed on the balance plate 81, in a normal state, the positions of the culture devices 8 on the lifting devices 7 are always higher than the horizontal plane in the water storage tank 2, the transmission devices 425 are in a power-off state under the driving of the rotating devices 4, the culture devices 8 perform circular motion around the fixed shafts 3 to drive surrounding air to circulate, air circulation is promoted, and the light receiving condition of each tissue culture seedling pot is adjusted; when the whole body is irrigated at the same time in an irrigation state (irrigation by a basin soaking method), the transmission device 425 and the planet pinion 423 are in an electrified state, under the electromagnetic action, the planet pinion 423 and the driven gear 4251 rotate synchronously, the multiple groups of rotating devices 4 are driven by the double-shaft motor 41 simultaneously, further the sun gear 422 rotates clockwise to drive the planet pinion 423 to revolve clockwise, further the cultivation device 8 rotates clockwise around the fixed shaft 3, simultaneously the planet pinion 423 and the driven gear 4251 rotate anticlockwise synchronously to drive the rack 4252 to diverge outwards, further the cultivation device 8 moves towards the direction far away from the central axis of the fixed shaft 3, when the cultivation basin 82 can be completely soaked in the water storage tank 2, the transmission device 425 is powered off, and the transmission device 425 and the planet pinion 423 are in a slipping state, then, cultivating device 8 rotates around fixed shaft 3 to perform pot soaking irrigation, after irrigation is completed, transmission device 425 and planetary pinion 423 are electrified again, sun gear 422 rotates anticlockwise to drive planetary pinion 423 to revolve anticlockwise, further cultivating device 8 rotates anticlockwise around fixed shaft 3, planetary pinion 423 and driven gear 4251 rotate clockwise synchronously, further rack 4252 is driven to move towards the central axis direction of fixed shaft 3, further cultivating device 8 moves towards the central axis direction of fixed shaft 3, after cultivating device 8 returns to the normal state lower position, transmission device 425 is powered off, cultivating device 8 is fixed in position, irrigation is performed on single or multiple cultivating pots 82 if needed, and under the feedback of a humidity monitoring device on balance plate 81, only power on and power off operation is needed to be performed on corresponding transmission device 425.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be considered to be within the technical scope of the present invention, and the technical solutions and the inventive concepts thereof according to the present invention are equivalent to or changed within the technical scope of the present invention.

Claims (4)

1. The utility model provides an indoor cultivation regulation and control economizer of national orchid tissue culture seedling which characterized in that: the method comprises the following steps:

the rack (1) bears working equipment, and the bottom of the rack is provided with a roller;

the water storage tank (2) is fixed on the rack (1);

the two ends of the fixed shaft (3) are fixed on the rack (1), and the middle part of the fixed shaft is positioned above the water storage tank (2);

the rotating devices (4) are linearly distributed and are fixed on the fixed shaft (3);

two fixed disks (5) are symmetrically distributed, and the centers of the two fixed disks are fixed on the fixed shaft (3);

the sleeve shaft (6) is fixed on the fixed shaft (3) and positioned between the fixed disks (5);

a plurality of groups of lifting devices (7) are distributed in an annular manner and are connected with the outer wall of the sleeve shaft (6) in a sliding manner;

the cultivation device (8) is rotationally fixed between the lifting devices (7);

the rotating device (4) comprises:

a double-shaft motor (41) fixed inside the fixed shaft (3);

the two planet wheels (42) are symmetrically distributed and are respectively in rotary connection with two sides of the double-shaft motor (41);

the planet wheel (42) comprises:

a rotating shaft (421) which is rotationally connected with the double-shaft motor (41);

the center of the sun gear (422) is fixedly connected with the rotating shaft (421);

a plurality of planet pinions (423) which are annularly distributed and meshed with the sun gear (422);

the outer ring of the gear ring (424) is fixed on the inner wall of the sleeve shaft (6), and the inner ring of the gear ring is meshed with the planet pinion (423);

the transmission devices (425) are annularly distributed and provided with a plurality of groups and are in electromagnetic connection with the planet pinions (423);

the planet pinion (423) penetrates through the fixed shaft (3) to be connected with the sun gear (422) and the gear ring (424), and the transmission device (425) penetrates through the fixed shaft (3) and the sleeve shaft (6) to be connected with the lifting device (7) in a sliding mode;

the transmission (425) comprises:

a driven gear (4251) electromagnetically connected to the planetary pinion gear (423);

a rack (4252) that meshes with the driven gear (4251);

the connector (4253) is fixed at one end of the rack (4252) far away from the driven gear (4251) and is in sliding connection with the lifting device (7);

each set of said actuators (425) being not in the same plane;

the sleeve shaft (6) is fixed between the fixed disks (5) and fixedly connected with the fixed disks (5), and a plurality of annular holes corresponding to the racks (4252) are formed in the sleeve shaft (6).

2. The indoor cultivation, regulation and energy conservation device for tissue culture seedlings of Chinese orchid according to claim 1, characterized in that: the lifting device (7) comprises:

a plurality of groups of slide ways (71) which correspond to the transmission device (425) and are fixed on the outer wall of the sleeve shaft (6) in a sliding way;

and the sliding block (72) is fixed on the sliding way (71) in a sliding way and is fixedly connected with the connecting head (4253).

3. The indoor cultivation, regulation and energy conservation device for tissue culture seedlings of Chinese orchid according to claim 2, characterized in that: the length of the slide way (71) is less than the shortest distance from the sleeve shaft (6) to the water storage tank (2).

4. The indoor cultivation, regulation and energy conservation device for tissue culture seedlings of Chinese orchid according to claim 1, characterized in that: the cultivation device (8) comprises:

the two ends of the balance plate (81) are rotationally connected with the sliding block (72), and the middle part of the balance plate is provided with a cultivation hole and a humidity monitoring device;

and a cultivation pot (82) fixed on the cultivation hole of the balance plate (81).

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