CN211745656U - Strawberry seedling growing device - Google Patents

Abstract

The application provides a strawberry device of growing seedlings, this strawberry device of growing seedlings includes: a seedling raising tank, a microbial inoculum box, a plug tray and a circulating pump; the microbial inoculum box is communicated with the seedling culture groove and is used for inputting bacterial liquid into the seedling culture groove; the plug tray is arranged in the seedling culture groove, and the bottom of the plug tray is arranged to be soaked in the bacterial liquid; the circulating pump is communicated with the seedling raising tank and the microbial inoculum box and is used for circulating the bacterial liquid between the seedling raising tank and the microbial inoculum box, and the circulating pump is provided with an adjusting valve for adjusting the circulating speed of the bacterial liquid. This strawberry device of growing seedlings can improve inoculation efficiency and the quality of growing seedlings.

Description

Strawberry seedling growing device

Technical Field

The application relates to the technical field of agricultural seedling culture, in particular to a strawberry seedling culture device.

Background

Strawberry is popular among people because of being rich in various vitamins, high in nutritive value, fragrant and sweet in taste and the like. However, the quality of strawberries on the market is uneven, and the quality of the strawberries is partially determined by the quality of strawberry seedlings. In the existing breeding technology and measures, the method mainly takes the culture of virus-free strawberry commercial seedlings as a way for improving the quality of strawberry seedlings. In recent years, the rapid development of biological agents provides a brand-new technology for the high-quality breeding of strawberry seedlings, but the strawberry seedlings have small root systems, slow bacterial liquid permeation and high inoculation difficulty.

SUMMERY OF THE UTILITY MODEL

An object of the embodiment of this application is to provide a strawberry device of growing seedlings, this strawberry device of growing seedlings can improve inoculation efficiency and the quality of growing seedlings.

The embodiment of the application provides a strawberry device of growing seedlings, this strawberry device of growing seedlings includes: a seedling raising tank, a microbial inoculum box, a plug tray and a circulating pump; the microbial inoculum box is communicated with the seedling culture groove and is used for inputting bacterial liquid into the seedling culture groove; the plug tray is arranged in the seedling culture groove, and the bottom of the plug tray is arranged to be soaked in the bacterial liquid; the circulating pump is communicated with the seedling growing tank and the microbial agent box and used for enabling the bacterial liquid to circulate between the seedling growing tank and the microbial agent box, and the circulating pump is provided with an adjusting valve used for adjusting the circulating speed of the bacterial liquid.

In the implementation process, the bacterial liquid in the seedling raising tank is provided by the microbial inoculum box, and the circulating pump is arranged to enable the bacterial liquid in the seedling raising tank and the bacterial inoculum box to circulate, so that on one hand, the density of biological bacteria in the bacterial liquid in the seedling raising tank is reduced after the seedling raising tank is cultivated for a period of time, and further the inoculation efficiency is gradually reduced along with the advance of the time, so that the density of the biological bacteria in the bacterial liquid in the seedling raising tank can be kept balanced and stable through the circulation of the bacterial liquid, and further the inoculation efficiency is improved; on the other hand, the bacteria liquid circulation can enable the bacteria liquid to be in a flowing state, the flowing bacteria liquid can dissolve more oxygen, the activity of biological bacteria in the bacteria liquid is improved, and then the inoculation efficiency and the seedling quality are effectively improved. Because the root system of the strawberry is short and fragile, when the flow speed of the bacterial liquid is too high, the bacterial liquid may impact the strawberry substrate seedlings in the hole tray to damage the root system structure of the strawberry. The flow rate of the bacterial liquid is adjusted through the adjusting valve on the circulating pump, so that the bacterial liquid circulates in a low-speed and penetrating mode, strawberry matrix seedlings can be fully contacted with the bacterial liquid, and the inoculation efficiency can be further improved while strawberry matrix is protected.

In a possible implementation manner, the strawberry seedling raising device further comprises a flow meter, and the flow meter is communicated with the seedling raising groove and the microbial agent box and used for measuring the circulation speed of the bacterial liquid.

In the implementation process, the flowmeter is arranged, so that on one hand, an operator can monitor the flow rate of the bacteria liquid at any time; on the other hand, the operating personnel can carry out accurate regulation and control of fungus liquid circulation speed according to the velocity of flow of the fungus liquid that the flowmeter shows, improves the inoculation efficiency of fungus liquid.

In a possible implementation manner, a plurality of plug trays can be arranged in the seedling raising groove.

In the implementation process, a plurality of plug trays can be arranged in one seedling culture groove, and a plurality of plug trays can be used for simultaneously culturing seedlings in one seedling culture groove.

In a possible implementation manner, the strawberry seedling raising device further comprises a plug tray bracket, and the plug tray bracket is used for being configured in the seedling raising groove to limit the plug tray in a preset horizontal area.

In the implementation process, as the bacteria liquid in the seedling culture groove flows, when a plurality of hole trays are placed in the seedling culture groove at the same time and are in a free state, the hole trays can move left and right in the seedling culture groove, even collide with each other, and the inoculation efficiency of the bacteria liquid and the seedling culture quality are influenced. Therefore, the plug tray bracket is arranged in the seedling raising groove, the plug tray can be limited in a preset horizontal area in the seedling raising groove, and the plug tray is prevented from drifting and colliding.

In one possible implementation, the tray support includes a frame, and a plurality of cross bars and a plurality of longitudinal bars disposed within the frame; the frame is fixedly connected with the seedling culture groove; the plurality of transverse rods and the plurality of longitudinal rods are matched with the frame to configure a plurality of horizontal areas.

In the implementation process, the plug tray is limited at a preset position or area in a mode of combining the frame and the rod-shaped structure, the structure is simple, the occupied area of the rod-shaped structure is small, and the area of the seedling culture groove can be utilized to the maximum extent.

In one possible implementation, each of the cross bars is slidably connected to the frame; each of the side rails is slidably connected to the frame; the frame is provided with a first locking piece and a second locking piece, the first locking piece is used for fixing the transverse rod at a preset position, and the second locking piece is used for fixing the longitudinal rod at a preset position.

In the implementation process, the transverse rods and the longitudinal rods are arranged to be connected to the frame in a sliding mode, the size or the number of horizontal areas can be changed by moving the positions of the transverse rods and the longitudinal rods, and therefore the seedling raising groove can be suitable for plug trays of different sizes or different numbers.

In a possible implementation manner, the strawberry seedling raising device further comprises a partition board, the partition board is used for being configured in the seedling raising groove to support the plug tray, and the bacterial liquid can penetrate through the partition board.

In the implementation process, in order to enable the bacterial liquid to be in full contact with the strawberry substrate seedlings and improve the inoculation efficiency, the depth of the bacterial liquid in the seedling culture groove is larger than that of the plug tray, so that the plug tray is supported by the partition plate, and the bottom of the plug tray is soaked in the bacterial liquid.

In a possible realization mode, the height position of the partition board in the seedling raising groove is adjustable.

In the implementation process, in the actual seedling raising, the depth of the plug tray or the strawberry substrate seedlings soaked in the bacterial liquid is different under the influence of the seedling raising environment or other parameters of the seedling raising. Therefore, the partition plate is set to be height-adjustable, and an operator can adjust the depth of the plug tray or the strawberry substrate seedlings soaked in the bacterial liquid by adjusting the setting height of the partition plate.

In a possible implementation manner, the strawberry seedling raising device further comprises a first temperature control device, and the first temperature control device is used for regulating and controlling the temperature of the bacterial liquid in the bacterial agent box.

In the implementation process, the activity of the biological bacteria is closely related to the inoculation efficiency and the seedling quality, and the temperature greatly influences the activity of the biological bacteria. Therefore, the temperature in the microbial agent box is controlled by the first temperature control device, so that the activity of biological bacteria is improved, and the inoculation efficiency and the seedling quality are improved.

In a possible implementation manner, the strawberry seedling raising device further comprises a second temperature control device, and the second temperature control device is used for regulating and controlling the temperature of the bacterial liquid in the seedling raising groove.

In the implementation process, when the bacterial liquid in the microbial inoculum box is input into the seedling culture tank, the temperature of the bacterial liquid may be reduced, and in order to keep the activity of the biological bacteria in the bacterial liquid in an optimal state, a second temperature control device is arranged to regulate and control the temperature of the bacterial liquid in the seedling culture tank.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present application, the drawings that are required to be used in the embodiments of the present application will be briefly described below, it should be understood that the following drawings only illustrate some embodiments of the present application and therefore should not be considered as limiting the scope, and that those skilled in the art can also obtain other related drawings based on the drawings without inventive efforts.

Fig. 1 is a schematic structural diagram of a strawberry seedling raising device provided in an embodiment of the present application;

fig. 2 is a schematic structural diagram of an aperture plate holder according to an embodiment of the present disclosure.

Icon: 100-seedling raising tank; 200-a microbial inoculum box; 300-plug tray; 400-circulating pump; 500-a flow meter; 600-a plug support; 610-a frame; 620-cross bar; 630-a longitudinal bar; 640-horizontal area; 700-spacer.

Detailed Description

The technical solutions in the embodiments of the present application will be described below with reference to the drawings in the embodiments of the present application.

It should be noted that: like reference numbers and letters refer to like items in the following figures, and thus, once an item is defined in one figure, it need not be further defined and explained in subsequent figures. Meanwhile, in the description of the present application, the terms "first", "second", and the like are used only for distinguishing the description, and are not to be construed as indicating or implying relative importance.

In the prior art, tray substrate seedling has gradually replaced traditional soil seedling based on the development of biological agents. However, in the field of strawberry seedling culture, the root system of the strawberry is small, the penetration speed of the bacterial liquid is low, the inoculation difficulty is high, and the inoculation efficiency is low. Referring to fig. 1, fig. 1 is a schematic structural diagram of a strawberry seedling raising device provided in the present embodiment, and the present embodiment provides a strawberry seedling raising device including a seedling raising tank 100, a microbial inoculum box 200, a plug 300, and a circulation pump 400. The microbial inoculum box 200 is communicated with the seedling raising groove 100 and is used for inputting bacterial liquid into the seedling raising groove 100; the plug 300 is configured in the seedling raising tank 100, and the bottom of the plug 300 is configured to be soaked in the bacterial liquid; the circulating pump 400 is communicated with the seedling raising tank 100 and the microbial inoculum box 200, the circulating pump 400 is used for circulating the bacterial liquid between the seedling raising tank 100 and the microbial inoculum box 200, and the circulating pump 400 is provided with an adjusting valve for adjusting the circulating speed of the bacterial liquid.

In the implementation process, the plug 300 is placed in the seedling raising groove 100 to raise strawberry seedlings, the planted strawberry substrate seedlings are placed in the plug 300, when the plug 300 is placed in the seedling raising groove 100, the bottom of the plug 300 is soaked in the bacterial liquid of the seedling raising groove 100, and the strawberry substrate seedlings in the plug 300 are in contact with or soaked in the bacterial liquid. The bacterial liquid in the seedling raising tank 100 is provided by the bacterial agent box 200, and the circulating pump 400 is arranged to circulate the bacterial liquid in the seedling raising tank 100 and the bacterial agent box 200, so that on one hand, the density of the biological bacteria in the bacterial liquid in the seedling raising tank 100 is reduced after the bacterial liquid is cultured for a period of time, and further the inoculation efficiency is gradually reduced along with the advance of the time, so that the density of the biological bacteria in the bacterial liquid in the seedling raising tank 100 can be kept balanced and stable through the circulation of the bacterial liquid, and further the inoculation efficiency is improved; on the other hand, the bacteria liquid circulation can enable the bacteria liquid to be in a flowing state, the flowing bacteria liquid can dissolve more oxygen, the activity of biological bacteria in the bacteria liquid is improved, and then the inoculation efficiency and the seedling quality are effectively improved. Because the root system of the strawberry is short and fragile, when the flow speed of the bacterial liquid is too high, the bacterial liquid may impact the strawberry substrate seedlings in the plug 300, and damage the root system structure of the strawberry. The flow rate of the bacterial liquid is adjusted by the adjusting valve on the circulating pump 400, so that the bacterial liquid circulates in a low-speed and penetrating mode, strawberry matrix seedlings can be fully contacted with the bacterial liquid, and the inoculation efficiency can be further improved while strawberry matrix is protected.

The strawberry seedling raising device provided by the application is not only suitable for strawberries, but also suitable for raising seedlings of other plants, and the application does not limit the types of the raised seedlings.

In a possible implementation manner, the strawberry seedling raising device further includes a flow meter 500, and the flow meter 500 is communicated with the seedling raising tank 100 and the microbial inoculum box 200 and is used for measuring the circulation speed of the bacterial liquid.

In the implementation process, the flowmeter 500 is arranged, so that on one hand, an operator can monitor the flow rate of the bacteria liquid at any time; on the other hand, the operator can accurately regulate and control the bacteria liquid circulation speed according to the flow speed of the bacteria liquid displayed by the flowmeter 500, so that the inoculation efficiency of the bacteria liquid is improved.

In one possible implementation, the flow meter 500 is provided between the circulation pump 400 and the seedling tank 100.

In the implementation process, the flow meter 500 may be disposed between the circulation pump 400 and the microbial agent tank 200, or between the circulation pump 400 and the seedling raising tank 100. Set up flowmeter 500 between circulating pump 400 and seedling raising tank 100 for flowmeter 500 is close to seedling raising tank 100, and the velocity of flow that flowmeter 500 surveyed is closer to the speed that the fungus liquid got into seedling raising tank 100, and then realizes the more accurate regulation to the flow velocity of the fungus liquid in seedling raising tank 100, improves the inoculation efficiency of fungus liquid.

In the prior art, only one plug 300 is generally arranged in one seedling raising groove 100, so that the seedling raising efficiency and the utilization rate of the strawberry seedling raising device are low.

In one possible implementation, a plurality of plug trays 300 may be disposed in the nursery sock 100.

In the above implementation process, a plurality of plug trays 300 may be disposed in one seedling raising tank 100, and a plurality of plug trays 300 may be used for raising seedlings in one seedling raising tank 100 at the same time.

Referring to fig. 2, fig. 2 is a schematic structural diagram of a plug tray support 600 provided in an embodiment of the present application, and in a possible implementation manner, the strawberry seedling raising device further includes a plug tray support 600, where the plug tray support 600 is configured in the seedling raising tank 100 to limit the plug tray 300 in the predetermined horizontal area 640.

In the above implementation process, since the bacteria liquid in the seedling raising tank 100 is flowing, when a plurality of plug trays 300 are placed in the seedling raising tank 100 at the same time and are in a free state, the plug trays 300 can move left and right in the seedling raising tank 100, even collide with each other, and the inoculation efficiency of the bacteria liquid and the seedling raising quality are affected. Therefore, the tray holder 600 is provided in the seedling raising tank 100, so that the tray 300 can be limited to the predetermined horizontal area 640 in the seedling raising tank 100, and the tray 300 can be prevented from drifting and colliding.

In one possible implementation, the tray support 600 includes a frame 610 and a plurality of cross bars 620 and a plurality of longitudinal bars 630 disposed within the frame 610; the frame 610 is fixedly connected to the seedling raising tank 100; the plurality of cross bars 620 and the plurality of longitudinal bars 630 cooperate with the frame 610 to define a plurality of horizontal regions 640.

In the above implementation process, the frame 610 is combined with the rod-shaped structure to limit the plug 300 at a predetermined position or area, the structure is simple, the occupied area of the rod-shaped structure is small, and the area of the seedling raising tank 100 can be utilized to the maximum. It should be noted that the cross bar 620 and the longitudinal bar 630 are vertically mounted on the frame 610.

In one possible implementation, each crossbar 620 is slidably connected to the frame 610; each side rail 630 is slidably connected to the frame 610; the frame 610 is provided with a first locking member for fixing the cross bar 620 at a predetermined position and a second locking member for fixing the longitudinal bar 630 at a predetermined position.

In the implementation process, the transverse rods 620 and the longitudinal rods 630 are slidably connected to the frame 610, and the size or the number of the horizontal areas 640 can be changed by moving the positions of the transverse rods 620 and the longitudinal rods 630, so that the seedling raising tank 100 can be suitable for plug trays 300 with different sizes or different numbers.

In one possible implementation, the frame 610 is removably attached to the nursery sock 100.

In the implementation process, the frame 610 is detachably connected to the seedling raising tank 100, so that the frame 610 and the seedling raising tank 100 can be replaced and maintained conveniently.

In a possible implementation manner, the strawberry seedling raising device further comprises a partition plate 700, the partition plate 700 is used for being arranged in the seedling raising tank 100 to support the plug 300, and the bacteria liquid can penetrate through the partition plate 700.

In the implementation process, generally, in order to enable the bacterial liquid to be in full contact with the strawberry substrate seedlings and improve the inoculation efficiency, the depth of the bacterial liquid in the seedling raising tank 100 is greater than that of the plug 300, so that the plug 300 is supported by the partition plate 700, and the bottom of the plug 300 is soaked in the bacterial liquid. When the tray support 600 is disposed in the seedling raising tank 100, the partition 700 is disposed below the tray support 600.

In one possible implementation, the height position of the partition 700 in the seedling raising tank 100 is adjustable.

In the above implementation process, in the actual seedling raising, the depth of the plug 300 or the strawberry substrate seedling soaked in the bacterial liquid is different under the influence of the seedling raising environment or other parameters of the seedling raising. Therefore, the height of the partition plate 700 is adjustable, and an operator can adjust the depth of the plug 300 or the strawberry substrate seedlings soaked in the bacterial liquid by adjusting the height of the partition plate 700.

In a possible implementation manner, the strawberry seedling raising device further comprises a first temperature control device, and the first temperature control device is used for regulating and controlling the temperature of the bacterial liquid in the bacterial agent box 200.

In the implementation process, the activity of the biological bacteria is closely related to the inoculation efficiency and the seedling quality, and the temperature greatly influences the activity of the biological bacteria. Therefore, the first temperature control device is arranged to control the temperature in the microbial agent box 200, so that the activity of biological bacteria is improved, and the inoculation efficiency and the seedling quality are improved.

In a possible implementation manner, the strawberry seedling raising device further includes a second temperature control device, and the second temperature control device is used for regulating and controlling the temperature of the bacterial liquid in the seedling raising tank 100.

In the above implementation process, when the bacteria liquid in the bacteria agent box 200 is input into the seedling raising tank 100, the temperature of the bacteria liquid may be reduced, and in order to keep the activity of the biological bacteria in the bacteria liquid in the optimal state, the second temperature control device is arranged to control the temperature of the bacteria liquid in the seedling raising tank 100.

The above description is only an example of the present application and is not intended to limit the scope of the present application, and various modifications and changes may be made by those skilled in the art. Any modification, equivalent replacement, improvement and the like made within the spirit and principle of the present application shall be included in the protection scope of the present application. It should be noted that: like reference numbers and letters refer to like items in the following figures, and thus, once an item is defined in one figure, it need not be further defined and explained in subsequent figures.

The above description is only for the specific embodiments of the present application, but the scope of the present application is not limited thereto, and any person skilled in the art can easily conceive of the changes or substitutions within the technical scope of the present application, and shall be covered by the scope of the present application. Therefore, the protection scope of the present application shall be subject to the protection scope of the claims.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrase "comprising an … …" does not exclude the presence of other identical elements in a process, method, article, or apparatus that comprises the element.

Claims (10)

1. A strawberry device of growing seedlings, its characterized in that includes:

a seedling raising tank;

the microbial inoculum box is communicated with the seedling culture groove and is used for inputting bacterial liquid into the seedling culture groove;

the plug tray is configured in the seedling culture groove, and the bottom of the plug tray is configured to be soaked in the bacterial liquid;

and the circulating pump is communicated with the seedling raising tank and the microbial agent box and is used for circulating the bacterial liquid between the seedling raising tank and the microbial agent box, and the circulating pump is provided with an adjusting valve for adjusting the circulating speed of the bacterial liquid.

2. A strawberry seedling raising apparatus according to claim 1, further comprising:

and the flowmeter is communicated with the seedling culture tank and the microbial inoculum box and is used for measuring the circulation speed of the bacteria liquid.

3. A strawberry seedling raising device according to claim 1, wherein a plurality of the plug trays are disposed in the seedling raising tank.

4. A strawberry seedling raising apparatus according to claim 3, further comprising:

and the plug tray bracket is used for being configured in the seedling raising groove so as to limit each plug tray in a preset horizontal area.

5. A strawberry seedling raising device according to claim 4, wherein the tray support comprises a frame and a plurality of cross bars and a plurality of longitudinal bars disposed within the frame;

the frame is fixedly connected with the seedling culture groove; the plurality of transverse rods and the plurality of longitudinal rods are matched with the frame to configure a plurality of horizontal areas.

6. A strawberry seedling growing device according to claim 5, wherein each cross bar is slidably connected to the frame; each of the side rails is slidably connected to the frame;

the frame is provided with a first locking piece and a second locking piece, the first locking piece is used for fixing the transverse rod at a preset position, and the second locking piece is used for fixing the longitudinal rod at a preset position.

7. A strawberry seedling raising device according to any one of claims 1 to 6, further comprising: and the partition plate is used for being configured in the seedling raising groove to support the plug tray, and the bacteria liquid can penetrate through the partition plate.

8. A strawberry seedling raising device according to claim 7, wherein the height position of the partition plate in the seedling raising tank is adjustable.

9. A strawberry seedling raising device according to claim 7, further comprising:

the first temperature control device is used for regulating and controlling the temperature of the bacterium liquid in the bacterium agent box.

10. A strawberry seedling raising apparatus according to claim 9, further comprising:

and the second temperature control device is used for regulating and controlling the temperature of the bacterial liquid in the seedling culture tank.

Images