CN117694141A - Gardens flowers cultivation device of growing seedlings - Google Patents

Abstract

The invention provides a garden flower seedling cultivation device, which relates to the technical field of garden flower seedling cultivation and comprises: the device comprises a cultivation pond, a windproof heat preservation shed, a controller, a light sensor, a first displacement bracket, a first displacement seat, a second displacement seat and a second displacement bracket; culture solution is contained in the cultivation pool, the cultivation pool is of a rectangular pool-shaped structure, one end of the cultivation pool is upwards covered with a windproof heat preservation shed, a fluid infusion pipe and a blow-down pipe are arranged on the side wall of the other end of the cultivation pool, and the blow-down pipe is arranged below and used for evacuating solution in the pool. According to the invention, the cultivated seedlings are planted in the second displacement bracket, the second displacement bracket can work through the second motor, so that the second displacement bracket can slide out of one side of the first displacement bracket, the cultivation seedlings are convenient and quick, operators can finish the cultivation by standing on one side, butt joint is not required at the other end of the cultivation pool, the operators do not need to enter the pool to support, the cleaning of solution in the cultivation pool can be ensured, and the labor intensity of the operators is reduced.

Description

Gardens flowers cultivation device of growing seedlings

Technical Field

The invention relates to the technical field of garden flower seedling raising, in particular to a garden flower seedling raising and cultivating device.

Background

Traditional flower seedling raising and cultivation generally depend on manual operation, are time-consuming and labor-consuming, and cannot be accurately controlled. Therefore, how to realize automation and intellectualization of flower seedling raising and cultivation and improve the growth efficiency and quality of flowers is a problem to be solved in the current garden flower seedling raising and cultivation field.

To solve this problem, some techniques are applied to flower seedling and cultivation. For example, the forcing culture of flowers can be performed by using a cooling bed and a warming bed. The flowers can be kept to bloom in the winter, so that the flowers can not overwinter in the open field in winter. In addition, the cellar is also a simple temporary facility for winter protection and overwintering in winter, and can be used for supplementing the defects of the cold room.

However, these techniques still present some problems and challenges. For example, the manner in which cold and warm beds are protected from wintering may be affected by climatic conditions, such as temperature, humidity, etc. The cellar can supplement the shortage of the cold room, but has higher construction and maintenance cost.

Therefore, there is a need to develop a garden flower seedling cultivation device capable of automatic control and intelligent adjustment. The device can automatically adjust environmental parameters such as temperature, humidity and the like, and provides a proper growth environment for flowers. Meanwhile, the device has the advantages of simple operation, high automation degree, high growth efficiency and the like.

Disclosure of Invention

The invention relates to a garden flower seedling cultivation device, cultivation seedlings are planted in a second displacement bracket, the second displacement bracket can work through a second motor, so that the second displacement bracket can slide out of one side of a first displacement bracket, the garden flower seedling cultivation device is convenient and quick, an operator can finish the cultivation by standing on one side, the other end of a cultivation pool is not required to be butted, the operator also does not need to enter the pool to support, the cleaning of solution in the cultivation pool can be ensured, and the labor intensity of the operator is reduced.

The invention provides a garden flower seedling cultivation device, which specifically comprises a cultivation pool, a windproof heat preservation shed, a controller, a light sensor, a first displacement bracket, a first displacement seat, a second displacement seat and a second displacement bracket; the cultivation pond is provided with a culture solution, one end of the cultivation pond is covered with a windproof heat preservation shed upwards, the side wall of the other end of the cultivation pond is provided with a fluid supplementing pipe and a blow-down pipe, the blow-down pipe is positioned below and used for exhausting solution in the pond, the fluid supplementing pipe is positioned above and used for supplementing solution, and the fluid supplementing pipe and the blow-down pipe are respectively provided with an electric control valve; a controller and a light sensor are fixedly arranged on the side wall of one end where the liquid supplementing pipe and the blow-down pipe are positioned; the upper end of the cultivation pond is slidably provided with a first displacement bracket, the first displacement bracket is slidably provided with a second displacement bracket, a corner of the first displacement bracket is fixedly provided with a first displacement seat, the first displacement seat is positioned at the corner of one end where the controller is positioned on the cultivation pond, and the inner end of the side edge of the second displacement bracket opposite to the windproof heat preservation shed is fixedly provided with a second displacement seat.

Optionally, a first displacement rack is fixedly arranged at the upper end of the side wall of one end of the second displacement bracket which can be slipped and unloaded on the cultivation pool;

the top clamping grooves are formed in the upper ends of the left tank wall and the right tank wall of the cultivation tank along the sliding direction of the first displacement bracket, the side clamping grooves are formed in the tank walls on the left side and the right side and correspond to the top clamping grooves, and the depth directions of the top clamping grooves and the side clamping grooves are in a vertical state.

Optionally, the wind-proof heat preservation shed is of a high-temperature transparent film structure, the wind-proof heat preservation shed is of a dome-shaped structure, one end of the wind-proof heat preservation shed is of a closed end, the other end of the wind-proof heat preservation shed is of an open end, the open end faces into the pool, and a ventilation fan is fixedly arranged on the closed end of the wind-proof heat preservation shed.

Optionally, the middle part of the first displacement bracket is a through hole penetrating up and down, the through hole corresponds to the inner cavity of the cultivation pool, and a second displacement rack is fixedly arranged at the lower end of the side wall of one end of the first displacement bracket, where the second displacement seat is located;

the end, away from the first displacement rack, of the first displacement bracket is fixedly blocked with a stop magnetic plate, the stop magnetic plate is attracted with one end, corresponding to the second displacement bracket, of the first displacement bracket, and the end, close to the first displacement rack, of the first displacement bracket is an open end;

the side walls of the left end and the right end of the inner cavity of the first displacement bracket are respectively provided with a first clamping rail towards the open end, and the position of the first clamping rail close to the open end of the first displacement bracket is an inclined chamfer structure;

the first displacement bracket bottom plane is provided with an inverted U-shaped clamping plate corresponding to the side wall of the cultivation pool.

Optionally, a first motor is vertically and fixedly installed on the first displacement seat, a first displacement gear is fixedly connected with a rotating shaft of the first motor downwards, and the first displacement gear is meshed with the first displacement rack.

Optionally, a second motor is vertically and fixedly installed on the second displacement seat, a rotating shaft of the second motor is downwards and fixedly connected with a second displacement gear, and the second displacement gear is meshed with a second displacement rack;

and a radar liquid level sensor facing the solution in the cultivation pond is fixedly arranged on the second displacement seat and is electrically connected with the controller.

Optionally, the left and right ends of second displacement bracket are respectively horizontal extension and are equipped with direction side exhibition pterygoid lamina, and vertical rotation interval evenly is equipped with the side pulley on the direction side exhibition pterygoid lamina, and the side pulley is "word wheel structure, and side pulley and first card rail slip looks joint, and grid infiltration hole that the interval is even is seted up to the bottom plate of second displacement bracket, is equipped with the barre on the front end lateral wall of second displacement bracket.

Optionally, time module and wireless sensing module have been built-in the controller, time module is used for time timing and timing, wireless sensing module is used for being connected with outside mobile device, time module is used for setting for time, and light sensor gathers the light condition when light condition is suitable for cultivation seedling growth, and in the settlement time, first motor work shifts out first displacement bracket from prevent wind the heat preservation canopy, light is not enough or after the time has arrived, shift into first displacement bracket from prevent wind the heat preservation canopy again, radar liquid level sensor is used for detecting whether solution liquid level satisfies the growth demand, if not, the automatically controlled valve on the control fluid infusion pipe is opened and is mended liquid.

The invention provides a garden flower seedling cultivation device, which has the following beneficial effects:

1. according to the invention, the cultivated seedlings are planted in the second displacement bracket, the second displacement bracket can work through the second motor, so that the second displacement bracket can slide out of one side of the first displacement bracket, the cultivation seedlings are convenient and quick, operators can finish the cultivation by standing on one side, butt joint is not required at the other end of the cultivation pool, the operators do not need to enter the pool to support, the cleaning of solution in the cultivation pool can be ensured, and the labor intensity of the operators is reduced.

2. When the light condition is suitable for growth of cultivated seedlings, and in the set time, the first motor works, the first displacement bracket is moved out of the windproof heat preservation shed, after the light is insufficient or the time is up, the first displacement bracket is moved in from the windproof heat preservation shed, the radar liquid level sensor is used for detecting whether the liquid level of the solution meets the growth requirement, if not, the electric control valve on the liquid supplementing pipe is controlled to be opened for supplementing liquid, the intelligent automatic seedling raising effect can be realized, personnel do not need to take care of in real time, and the intelligent automatic seedling raising device is convenient and quick and can be used for large-area efficient cultivation.

Drawings

In order to more clearly illustrate the technical solution of the embodiments of the present invention, the drawings of the embodiments will be briefly described below.

The drawings described below are only for illustration of some embodiments of the invention and are not intended to limit the invention.

In the drawings:

FIG. 1 shows a schematic view of the upper right front side of the present invention in an isometric view;

FIG. 2 shows a schematic view of the upper left rear perspective of the present invention;

FIG. 3 is a schematic diagram showing an isometric view of a second displacement carriage of the present invention in an extracted state;

FIG. 4 shows a schematic view of the lower perspective of a second displacement bracket of the present invention;

FIG. 5 shows a schematic diagram of the axial view of a portion of the windless insulation shed of the present invention;

FIG. 6 shows a schematic view of an isometric view of a first displacement carriage portion of the present invention;

FIG. 7 shows a schematic view of a partly semi-sectioned structure of a cultivation pond according to the invention;

fig. 8 shows a block diagram of the system architecture of the present invention.

List of reference numerals

1. A cultivation pool; 101. a fluid supplementing pipe; 102. blow-down pipe; 103. a first displacement rack; 104. a top clamping groove; 105. a side clamping groove;

2. wind-proof heat-preserving shed; 201. a ventilation fan;

3. a controller;

4. a light-sensitive sensor;

5. a first displacement bracket; 501. a first clamping rail; 502. a stop magnetic plate; 503. a second displacement rack; 504. a clamping plate;

6. a first displacement seat; 601. a first motor; 602. a first displacement gear;

7. a second displacement seat; 701. a second motor; 702. a second shifting gear; 703. a radar level sensor;

8. a second displacement carriage; 801. guiding the lateral spreading wing plate; 802. a handle bar; 803. a side pulley; 804. the grid wets the holes.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention more clear, the technical solutions of the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings of the embodiments of the present invention. It will be apparent that the described embodiments are some, but not all, embodiments of the invention. All other embodiments, which can be made by a person skilled in the art without creative efforts, based on the described embodiments of the present invention fall within the protection scope of the present invention.

Embodiment one: please refer to fig. 1 to 8:

the invention provides a garden flower seedling cultivation device, which comprises: the cultivation pond 1, the windproof heat preservation shed 2, the controller 3, the light sensor 4, the first displacement bracket 5, the first displacement seat 6, the second displacement seat 7 and the second displacement bracket 8; culture solution is contained in the culture pond 1, the culture pond 1 is of a rectangular pond-shaped structure, one end of the culture pond 1 is upwards covered with a windproof heat preservation shed 2, the side wall of the other end of the culture pond 1 is provided with a fluid supplementing pipe 101 and a blow-down pipe 102, the blow-down pipe 102 is positioned below and used for exhausting solution in the pond, the fluid supplementing pipe 101 is positioned above and used for supplementing solution, and electric control valves are respectively arranged on the fluid supplementing pipe 101 and the blow-down pipe 102; a controller 3 and a light sensor 4 are fixedly arranged on the side wall of one end where the liquid supplementing pipe 101 and the blow-down pipe 102 are positioned on the cultivation pool 1; the upper end of the cultivation pond 1 is slidably provided with a first displacement bracket 5, the first displacement bracket 5 is slidably provided with a second displacement bracket 8, a corner of the first displacement bracket 5 is fixedly provided with a first displacement seat 6, the first displacement seat 6 is positioned at the corner of one end where the controller 3 is positioned on the cultivation pond 1, and the inner end of the side edge of the second displacement bracket 8 opposite to the windproof heat preservation shed 2 is fixedly provided with a second displacement seat 7.

Wherein, the upper end of the side wall of one end of the second displacement bracket 8 which can be slipped and unloaded on the cultivation pool 1 is fixedly provided with a first displacement rack 103;

the upper ends of the left and right tank walls of the cultivation tank 1 are provided with top clamping grooves 104 along the sliding direction of the first displacement bracket 5, and the tank walls on the left and right sides are provided with side clamping grooves 105 corresponding to the top clamping grooves 104, and the depth directions of the top clamping grooves 104 and the side clamping grooves 105 are in a vertical state.

Wherein, prevent wind heat preservation canopy 2 is high temperature transparent film structure, prevent wind heat preservation canopy 2 and be dome structure, prevent wind the one end of heat preservation canopy 2 and be the blind end, one end is the open end, in the open end orientation pond, fixed mounting has ventilator 201 on the blind end of prevent wind heat preservation canopy 2, can be used to preserve heat for gardens flower cultivation seedling, improves growth efficiency.

The middle part of the first displacement bracket 5 is a through hole penetrating up and down, the through hole corresponds to the inner cavity of the cultivation pool 1, and a second displacement rack 503 is fixedly arranged at the lower end of the side wall of one end of the first displacement bracket 5 where the second displacement seat 7 is positioned;

the end of the first displacement bracket 5 far away from the first displacement rack 103 is fixedly blocked with a stop magnetic plate 502, one end of the stop magnetic plate 502 corresponding to the second displacement bracket 8 is attracted, and the end of the first displacement bracket 5 near the first displacement rack 103 is an open end;

the side walls of the left end and the right end of the inner cavity of the first displacement bracket 5 are respectively provided with a first clamping rail 501 towards the open end, and the position of the first clamping rail 501 close to the open end of the first displacement bracket 5 is of an inclined chamfer structure, so that the second displacement bracket 8 can be conveniently and smoothly clamped in;

an inverted U-shaped clamping plate 504 is arranged on the bottom plane of the first displacement bracket 5 corresponding to the side wall of the cultivation pond 1, a first motor 601 is vertically and fixedly arranged on a first displacement seat 6, a first displacement gear 602 is fixedly connected with a rotating shaft of the first motor 601 downwards, the first displacement gear 602 is meshed with the first displacement rack 103, a second motor 701 is vertically and fixedly arranged on a second displacement seat 7, a second displacement gear 702 is fixedly connected with a rotating shaft of the second motor 701 downwards, and the second displacement gear 702 is meshed with the second displacement rack 503;

the radar level sensor 703 towards the solution in the pool of the cultivation pool 1 is fixedly mounted on the second displacement seat 7, the radar level sensor 703 is electrically connected with the controller 3, the left end and the right end of the second displacement bracket 8 are respectively horizontally extended and provided with a guide side spreading wing plate 801, the vertical rotation interval on the guide side spreading wing plate 801 is uniformly provided with a side pulley 803, the side pulley 803 is of an 8-shaped wheel structure, the side pulley 803 is clamped with the first clamping rail 501 in a sliding manner, the bottom plate of the second displacement bracket 8 is provided with grid infiltration holes 804 with uniform interval, the front end side wall of the second displacement bracket 8 is provided with a handle 802, cultivated seedlings are planted in the second displacement bracket 8, the second displacement bracket 8 can work through the second motor 701, so that the second displacement bracket 8 can slide out from one side of the first displacement bracket 5, the cultivation pool can be conveniently and quickly completed by an operator only needing to stand on one side, the other end of the cultivation pool 1 does not need to be butted, the operator does not need to enter the pool, the solution in the cultivation pool can be guaranteed, and the labor intensity of the operator can be reduced.

In the second embodiment, on the basis of the first embodiment, a time module and a wireless sensor module are built in the controller 3, the time module is used for time counting and timing, the wireless sensor module is used for being connected with an external mobile device, the time module is used for setting time, the light sensor 4 collects the current light condition, when the light condition is suitable for the growth of cultivated seedlings, and in the setting time, the first motor 601 works to move the first displacement bracket 5 out of the windproof heat preservation shed 2, after the light is insufficient or the time is up, the first displacement bracket 5 is moved in from the windproof heat preservation shed 2, the radar liquid level sensor 703 is used for detecting whether the liquid level of a solution meets the growth requirement, if not, the electronic control valve on the liquid supplementing pipe 101 is controlled to be opened for supplementing liquid, the effect of intelligent automatic seedling culture can be achieved, the personnel do not need to look at in real time, and the method is convenient and fast, and efficient cultivation in a large area can be achieved.

The working principle of the embodiment is as follows: in the use process, flower seedlings to be cultivated are planted in the second displacement bracket 8 in advance, after the flower seedlings are planted, the second displacement bracket 8 is pushed in from one end of the first displacement bracket 5, the second motor 701 drives the second displacement gear 702 to enable the second displacement bracket 8 to be automatically clamped in the first displacement bracket 5, after the second displacement bracket is completely clamped in, seedling raising work is started, a preset culture solution is injected into the cultivation pond 1, a program for regularly receiving sunlight or not receiving sunlight is set, when the light condition is suitable for cultivating seedlings to grow, and in the set time, the first motor 601 works, the first displacement bracket 5 is moved out of the windproof heat insulation shed 2, after the light is insufficient or the time is up, the first displacement bracket 5 is moved in from the windproof heat insulation shed 2, the radar liquid level sensor 703 is used for detecting whether the liquid level of a solution meets the growth requirement, and if not, an electric control valve on the liquid supplementing pipe 101 is controlled to be opened for supplementing liquid.

In this context, the following points need to be noted:

1. the drawings of the embodiments of the present disclosure relate only to the structures related to the embodiments of the present disclosure, and reference may be made to the general design for other structures.

2. The embodiments of the present disclosure and features in the embodiments may be combined with each other to arrive at a new embodiment without conflict.

The foregoing is merely a specific embodiment of the disclosure, but the protection scope of the disclosure is not limited thereto, and any person skilled in the art can easily think about changes or substitutions within the technical scope of the disclosure, and it should be covered in the protection scope of the disclosure. Therefore, the protection scope of the present disclosure shall be subject to the protection scope of the claims.

Claims (8)

1. A garden flower seedling cultivation device comprises a cultivation pool (1), a windproof heat preservation shed (2), a controller (3), a light sensor (4), a first displacement bracket (5), a first displacement seat (6), a second displacement seat (7) and a second displacement bracket (8); the cultivation pool is characterized in that a cultivation pool (1) is filled with culture solution, the cultivation pool (1) is of a rectangular pool-shaped structure, one end of the cultivation pool (1) is covered with a windproof heat preservation shed (2) upwards, the side wall of the other end of the cultivation pool (1) is provided with a liquid supplementing pipe (101) and a blow-down pipe (102), the blow-down pipe (102) is positioned below and used for exhausting solution in the pool, the liquid supplementing pipe (101) is positioned above and used for supplementing solution, and electric control valves are respectively arranged on the liquid supplementing pipe (101) and the blow-down pipe (102); a controller (3) and a light sensor (4) are fixedly arranged on the side wall of one end where the liquid supplementing pipe (101) and the blow-down pipe (102) are positioned on the cultivation pool (1); the cultivation pond (1) is characterized in that a first displacement bracket (5) is slidably arranged at the upper end of the cultivation pond (1), a second displacement bracket (8) is slidably arranged on the first displacement bracket (5), a first displacement seat (6) is fixedly arranged at one corner of the first displacement bracket (5), the first displacement seat (6) is positioned at one end corner where a controller (3) is arranged on the cultivation pond (1), and a second displacement seat (7) is fixedly arranged at the inner end of the side edge of the second displacement bracket (8) opposite to the windproof heat preservation shed (2).

2. The garden flower seedling cultivation device according to claim 1, wherein a first displacement rack (103) is fixedly arranged at the upper end of the side wall of one end of the second displacement bracket (8) which can be slidably discharged on the cultivation pond (1);

top clamping grooves (104) are formed in the upper ends of the left tank wall and the right tank wall of the cultivation tank (1) along the sliding direction of the first displacement bracket (5), side clamping grooves (105) are formed in the left tank wall and the right tank wall corresponding to the top clamping grooves (104), and the top clamping grooves (104) and the side clamping grooves (105) are in vertical deep directions.

3. The garden flower seedling cultivation device according to claim 1, wherein the windproof heat preservation shed (2) is of a high-temperature transparent film structure, the windproof heat preservation shed (2) is of a dome-shaped structure, one end of the windproof heat preservation shed (2) is a closed end, the other end of the windproof heat preservation shed is an open end, the open end faces into a pool, and a ventilation fan (201) is fixedly arranged on the closed end of the windproof heat preservation shed (2).

4. The garden flower seedling cultivation device according to claim 2, wherein the middle part of the first displacement bracket (5) is a through hole penetrating up and down, the through hole corresponds to the inner cavity of the cultivation pond (1), and a second displacement rack (503) is fixedly arranged at the lower end of the side wall of one end of the first displacement bracket (5) where the second displacement seat (7) is positioned;

a stop magnetic plate (502) is fixedly blocked at one end of the first displacement bracket (5) far away from the first displacement rack (103), one end of the stop magnetic plate (502) corresponding to the second displacement bracket (8) is attracted, and one end of the first displacement bracket (5) close to the first displacement rack (103) is an open end;

first clamping rails (501) are respectively arranged on the side walls of the left end and the right end of the inner cavity of the first displacement bracket (5) towards the open end, and the positions of the first clamping rails (501) close to the open end of the first displacement bracket (5) are inclined chamfer structures;

an inverted U-shaped clamping plate (504) is arranged on the bottom plane of the first displacement bracket (5) corresponding to the side wall of the cultivation pool (1).

5. The garden flower seedling culture device according to claim 2, wherein the first motor (601) is vertically and fixedly arranged on the first displacement seat (6), a first displacement gear (602) is fixedly connected with a rotating shaft of the first motor (601) downwards, and the first displacement gear (602) is meshed with the first displacement rack (103).

6. The garden flower seedling culture device according to claim 5, wherein a second motor (701) is vertically and fixedly arranged on the second displacement seat (7), a second displacement gear (702) is fixedly connected with a rotating shaft of the second motor (701) downwards, and the second displacement gear (702) is meshed with the second displacement rack (503);

the second displacement seat (7) is fixedly provided with a radar liquid level sensor (703) facing the solution in the cultivation pool (1), and the radar liquid level sensor (703) is electrically connected with the controller (3).

7. The garden flower seedling culture device according to claim 4, wherein the left end and the right end of the second displacement bracket (8) are respectively horizontally extended and provided with a guiding lateral spreading wing plate (801), vertical rotation intervals on the guiding lateral spreading wing plate (801) are uniformly provided with lateral pulleys (803), the lateral pulleys (803) are of an 8-shaped wheel structure, the lateral pulleys (803) are clamped with the first clamping rail (501) in a sliding manner, a bottom plate of the second displacement bracket (8) is provided with grid infiltration holes (804) with uniform intervals, and the front end side wall of the second displacement bracket (8) is provided with a handle bar (802).

8. The garden flower seedling cultivation device according to claim 6, wherein the controller (3) is internally provided with a time module and a wireless sensor module, the time module is used for timing and timing, the wireless sensor module is used for being connected with an external mobile device, the time module is used for setting time, the light sensor (4) collects current light conditions, when the light conditions are suitable for cultivation seedling growth, and in the set time, the first motor (601) works, the first displacement bracket (5) is moved out of the windproof heat preservation shed (2), after the light is insufficient or the time is up, the first displacement bracket (5) is moved in from the windproof heat preservation shed (2), the radar liquid level sensor (703) is used for detecting whether the liquid level of the solution meets the growth requirement, and if not, an electric control valve on the liquid supplementing pipe (101) is controlled to be opened for supplementing liquid.