CN113265323A - Gibberellin is cultivateed with shaking activation equipment convenient to operation - Google Patents

Abstract

The invention is suitable for the technical field of gibberella culture, and provides a shake activation device for gibberella culture, which is convenient to operate, and the device comprises: the intermittent assembly is used for driving the feeding wheel to intermittently rotate so that the plurality of placing positions are sequentially connected with the feeding unit; the lifting assembly is used for driving the plurality of bearing tables to vibrate; the covering part is provided with a plurality of limiting covers which respectively correspond to the positions of the bearing platforms; and a transmission assembly; through intermittent type subassembly drive material loading wheel intermittent type nature rotation for in a plurality of culture mediums can intermittent type nature get into a plurality of cushion caps, material loading wheel rotatory a week back, a plurality of spacing lids close a plurality of cushion cap covers respectively just spacing to the culture medium, the power supplies power to lifting unit this moment, lifting unit begins to promote a plurality of cushion caps, and drive a plurality of culture mediums and vibrate, effectively avoid vibrating that activation equipment can't carry out automatic feeding and open the problem of vibration automatically to the culture medium automatically.

Description

Gibberellin is cultivateed with shaking activation equipment convenient to operation

Technical Field

The invention belongs to the technical field of cultivation of gibberella, and particularly relates to a shake activation device convenient to operate and used for cultivation of gibberella.

Background

The gibberellin is discovered when researching rice bakanae seedlings, the gibberellin can promote the rapid growth of plants, the dormancy of the plants can be relieved by treating seeds with the gibberellin, the seeds can be sown earlier, and a culture medium needs to be vibrated and activated in the process of culturing the gibberellin.

When the shock activation equipment for culturing gibberella on the market is used, a plurality of culture mediums need to be transported to the equipment and placed one by one and fixed, and then a switch for shock treatment is started.

Present gibberella is cultivateed with shaking activation equipment can not carry out automatic feeding to the culture medium, can not shake automatically after the material loading, needs artifical observation processing progress and regulates and control equipment and shake the processing, and the operation is inconvenient.

Disclosure of Invention

The embodiment of the invention aims to provide shock activation equipment for culturing gibberella, which is convenient to operate and aims to solve the problem that the shock activation equipment cannot automatically feed a culture medium and automatically start shock.

The embodiment of the invention is realized in such a way that the shake activation equipment for culturing the gibberella is convenient to operate, and the device comprises:

an operation table;

the feeding wheel is rotatably arranged on the operating platform, a plurality of circumferentially distributed placing positions are arranged on the feeding wheel, and a bearing platform is arranged in each placing position;

the intermittent assembly is arranged on the operating platform and used for driving the feeding wheel to rotate intermittently so that the plurality of placing positions are sequentially connected with the feeding unit;

the lifting assembly is arranged on the operating platform and is used for driving the plurality of supporting platforms to vibrate;

the covering part is provided with a plurality of limiting covers which respectively correspond to the positions of the bearing platforms; and

the transmission assembly is connected with the feeding wheel, and the feeding wheel can transmit the power of the intermittent assembly to the transmission assembly;

and after the feeding wheel rotates for a circle, the transmission assembly drives the covering piece to move to the plurality of limiting covers to be respectively closed with the plurality of supporting table covers, the first pole piece and the second pole piece are connected into a loop where the power supply and the lifting assembly are located, and the power supply supplies power to the lifting assembly to start the lifting assembly to lift.

Preferably, the feeding unit includes:

the feeding hopper is fixed on the operating platform; and

and the feeding pipe is connected with the feeding hopper and used for transporting the culture medium to the placing position.

Preferably, a sealing piece for sealing the feeding unit is arranged at the position where the covering piece is contacted with the feeding unit.

Preferably, the intermittent assembly comprises:

the driving wheel is rotatably arranged on the operating platform and is driven to rotate by the driving part; and

the driven wheel is coaxially and fixedly connected with the feeding wheel;

fixed columns with the same number as the placing bits are fixed on the driven wheel, and push rods interfering with the movement tracks of the fixed columns are fixed on the driving wheel.

Preferably, the transmission assembly comprises:

the transmission part is provided with a worm wheel rail and is connected with the feeding wheel through a connecting unit;

the limiting piece is fixedly arranged on the operating platform and is rotationally connected with the transmission piece; and

one end of the moving piece is connected with the capping piece, and the other end of the moving piece is rotationally connected with a rotating piece which is slidably arranged on the worm wheel rail;

the movable piece is in sliding fit with the positioning piece which is slidably arranged on the limiting piece.

Preferably, the connection unit includes:

the gear is coaxially and fixedly connected with the feeding wheel; and

and the gear ring is coaxially and fixedly installed with the transmission piece, and the gear ring is meshed with the gear.

Preferably, the lifting assembly comprises:

the bearing piece is arranged on the operating platform in a sliding mode and is connected with the output end of the driving source; and

the connecting piece is rotatably arranged on the bearing piece, lifting pieces with the same number as that of the bearing platforms are arranged on the connecting piece, and the connecting piece is rotatably connected with the feeding wheel;

the bearing platform interferes with the motion trail of the lifting piece, and when the lifting piece is driven to do reciprocating linear motion, the bearing platform can be pushed to realize oscillation.

According to the shock activation equipment for culturing the gibberella, provided by the embodiment of the invention, the intermittent assembly drives the feeding wheel to intermittently rotate, so that a plurality of culture mediums can intermittently enter a plurality of supporting platforms, after the feeding wheel rotates for a circle, a plurality of limiting covers just cover the plurality of supporting platforms to limit the culture mediums respectively, at the moment, the first pole piece and the second pole piece are butted to form a loop, the power supply supplies power to the lifting assembly, the lifting assembly starts to push the plurality of supporting platforms and drives the plurality of culture mediums to vibrate, and the problem that the shock activation equipment cannot automatically feed the culture mediums and automatically start vibration is effectively avoided.

Drawings

FIG. 1 is a schematic diagram of a shaking activation apparatus for cultivation of gibberellin fungi, which is convenient to operate according to an embodiment of the present invention;

FIG. 2 is a schematic diagram of a loading wheel of a shake activation apparatus for cultivation of gibberella, which is convenient to operate according to an embodiment of the present invention;

FIG. 3 is an enlarged view of a portion A of FIG. 2;

FIG. 4 is a schematic diagram of a batch assembly of a shaking activation apparatus for cultivation of gibberellin fungi, which is convenient to operate according to an embodiment of the present invention;

FIG. 5 is a schematic diagram of a transmission assembly of a shake activation apparatus for cultivation of gibberella, which is convenient to operate according to an embodiment of the present invention;

FIG. 6 is a schematic diagram of a connecting unit of a shake activation apparatus for cultivation of gibberellin fungi, which is convenient to operate according to an embodiment of the present invention;

in the drawings: 1. an operation table; 2. a feeding wheel; 3. a support platform; 4. a first pole piece; 5. a second pole piece; 6. a limiting cover; 7. a power source; 8. adding a cover component; 9. a closure member; 10. a connecting member; 11. a carrier; 12. a lifting member; 13. a drive source; 14. a driving wheel; 15. a drive member; 16. a push rod; 17. a driven wheel; 18. fixing a column; 19. a gear; 20. a ring gear; 21. a transmission member; 22. a worm-wheel rail; 23. a limiting member; 24. a rotating member; 25. a movable member; 26. a positioning member; 27. feeding into a hopper; 28. and a feeding pipe.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention is described in further detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

Specific implementations of the present invention are described in detail below with reference to specific embodiments.

As shown in fig. 1 to 3, a structure diagram of a shake activation apparatus for gibberella cultivation, which is convenient to operate according to an embodiment of the present invention, includes:

an operation table 1;

the feeding wheel 2 is rotatably arranged on the operating platform 1, a plurality of circumferentially distributed placing positions are arranged on the feeding wheel 2, and the placing positions are used for placing the supporting platform 3;

the intermittent assembly is arranged on the operating platform 1 and used for driving the feeding wheel 2 to intermittently rotate so that the plurality of placing positions are sequentially connected with the feeding unit;

the lifting assembly is arranged on the operating platform 1 and is used for driving the plurality of supporting platforms 3 to vibrate;

a covering component 8, on which a plurality of limit covers 6 corresponding to the positions of the plurality of bearing platforms 3 are arranged; and

the transmission assembly is connected with the feeding wheel 2, and the feeding wheel 2 can transmit the power of the intermittent assembly to the transmission assembly;

the first pole piece 4 that all is equipped with on every spacing lid 6, every bearing platform 3 all is equipped with the second pole piece 5 with the butt joint of first pole piece 4, and after material loading wheel 2 rotated the round, the drive assembly drive was covered piece 8 and is removed to a plurality of spacing lids 6 and is closed with a plurality of bearing platform 3 covers respectively, then first pole piece 4 and second pole piece 5 insert in the return circuit that power 7 and lift assembly belonged to, and power 7 supplies power to lift assembly promptly to start lift assembly and go up and down.

In one aspect of the present embodiment, the driving portion of the lifting assembly is the driving source 13, the driving source 13 may be a hydraulic cylinder, and besides, the driving source 13 may also be a component capable of performing linear motion, such as an air cylinder, an electric telescopic rod, and the like, which is not limited in this embodiment.

In addition, the cover 8 is provided with a power supply 7, and the power supply 7 is a rechargeable lithium battery, or a generator, etc., as long as power supply can be achieved, and the embodiment is not particularly limited herein.

The first pole piece 4 is electrically connected to the power source 7, and the second pole piece 5 is electrically connected to the lifting assembly, but the first pole piece 4 may also be electrically connected to the lifting assembly, and the second pole piece 5 is electrically connected to the power source 7, which is not limited herein.

It should be noted that, when the limiting cover 6 is covered with the supporting platform 3, the transmission assembly cannot continue to transmit, and the connecting unit is used for braking the feeding wheel 2 in a collision manner, so that the intermittent assembly is also braked in a collision manner, and only the lifting assembly works to vibrate the culture medium.

In practical application of this embodiment, the supporting platform 3 may be placed in a placing position, or may be connected by a spring, which is not specifically limited herein; the intermittent assembly drives the feeding wheel 2 to stop rotating every time, one bearing platform 3 is connected with the feeding unit, so that a culture medium in the feeding unit can enter the bearing platform 3, the other bearing platform 3 is connected with the feeding unit after the feeding wheel 2 rotates, the intermittent feeding of the feeding wheel 2 is realized by reciprocating in such a way, the feeding wheel 2 can drive the transmission assembly to start in the rotating process, the transmission assembly drives the covering piece 8 to move, the covering piece 8 just moves to the upper part of the feeding wheel 2 after the feeding wheel 2 rotates for a circle, so that the plurality of limiting covers 6 respectively cover the plurality of bearing platforms 3, namely, the culture medium is limited, at the moment, the first pole piece 4 is in butt joint with the second pole piece 5 to form a loop, the power supply 7 supplies power to the driving source 13, the lifting assembly starts to lift and push the plurality of bearing platforms 3, and the bearing platforms 3 slide relatively to the limiting covers 6 after being pushed, the cushion cap 3 can drive the culture medium to vibrate after being pushed, and the cushion cap 3 and the limit cap 6 are covered by a gap, so that the culture medium can vibrate more fully in the gap.

As shown in fig. 1, as a preferred embodiment of the present invention, the feeding unit includes:

a feeding hopper 27 fixed on the operation table 1; and

a feeding pipe 28 connected to the feeding hopper 27, said feeding pipe 28 being used to transport the culture medium to the placement position.

In one aspect of this embodiment, the feeding tube 28 is disposed obliquely, and the highest position of the feeding tube 28 is connected to the feeding hopper 27, and the lowest position of the feeding tube 28 is disposed toward the placing position, and the size of the feeding tube 28 is limited such that the culture medium can only be transported through the feeding tube 28 in sequence; of course, besides the above structure, the feeding unit may also be a structure with transportation performance such as a conveyor belt driven by a motor, and the feeding pipe 28 may also be provided with an auger as needed to transport the culture medium, which is not limited in this embodiment.

In the embodiment, in practical application, a plurality of culture mediums are put into the feeding hopper 27, and the plurality of culture mediums sequentially slide into the feeding pipe 28 and enter the supporting table 3 when the empty supporting table 3 is rotated to the outlet of the feeding pipe 28, at this time, the culture mediums entering the supporting table 3 block the outlet of the feeding pipe 28, so as to prevent other culture mediums in the feeding pipe 28 from continuously sliding out.

As shown in fig. 1 to 3, as another preferred embodiment of the present invention, a sealing member 9 for sealing the feeding unit is provided at a position where the capping member 8 contacts the feeding unit.

In practical application of the embodiment, when the covering part 8 descends to the plurality of limiting covers 6 and is respectively covered with the plurality of supporting platforms 3, the sealing part 9 is just positioned at the outlet of the feeding pipe 28 and blocks the outlet, so that the culture medium is prevented from sliding out of the feeding unit in the oscillation process; in one aspect of the present embodiment, the sealing member 9 may be a member having elasticity, such as a protective sponge, a silica gel column, etc., and is not particularly limited in the present embodiment.

As another preferred embodiment of the present invention, as shown in fig. 1 and 4, the intermittent assembly comprises:

a driving wheel 14 rotatably mounted on the operation table 1, wherein the driving wheel 14 is driven by a driving member 15 to rotate; and

the driven wheel 17 is coaxially and fixedly connected with the feeding wheel 2;

fixed columns 18 with the same number as the placing bits are fixed on the driven wheel 17, and push rods 16 interfering with the movement tracks of the fixed columns 18 are fixed on the driving wheel 14.

In one aspect of this embodiment, the driving member 15 can be a motor assembly, or a gear assembly or a belt pulley assembly driven by a motor, as long as the driving wheel 14 can rotate; besides the above structure, the intermittent assembly may further adopt an output motor connected to an encoder, and the encoder controls a rotation angle of an output end of the motor in each rotation.

In practical application of the embodiment, the driving part 15 drives the driving wheel 14 to rotate so as to drive the push rod 16 to rotate, when the push rod 16 is in contact with one fixed column 18, the push rod 16 continues to rotate and pushes the driven wheel 17 to rotate through the fixed column 18 until the push rod 16 rotates away from the fixed column 18, at this time, the initial position of the fixed column 18 is rotated to another fixed column 18, and the reciprocating operation is performed, so that the intermittent rotation of the driven wheel 17 is realized, and further the intermittent rotation of the feeding wheel 2 is realized.

As shown in fig. 1 and 5, as another preferred embodiment of the present invention, the transmission assembly includes:

the transmission piece 21 is provided with a worm wheel rail 22, and the transmission piece 21 is connected with the feeding wheel 2 through a connecting unit;

the limiting piece 23 is fixedly arranged on the operating platform 1 and is rotationally connected with the transmission piece 21; and

a movable member 25, one end of the movable member 25 being connected to the lid member 8, and the other end of the movable member 25 being rotatably connected to a rotating member 24 slidably mounted on the worm rail 22;

the movable member 25 is slidably engaged with a positioning member 26 slidably mounted on the limiting member 23.

In one aspect of this embodiment, the transmission assembly may be, in addition to the above structure, a lifting mechanism driven by a screw rod, or a component structure capable of achieving linear motion, and this embodiment is not limited in particular.

In practical application, when the transmission member 21 rotates, the worm wheel rail 22 on the transmission member rotates as well and drives the rotating member 24 to rotate, and since the limiting member 23 has a limiting effect on the positioning member 26 and the positioning member 26 has a limiting effect on the movable member 25, the worm wheel rail 22 drives the rotating member 24 to move along the worm wheel rail 22 when rotating, and drives the movable member 25 and the positioning member 26 to relatively slide, and the positioning member 26 and the limiting member 23 to relatively slide, thereby realizing the movement of the capping member 8; when the transmission member 21 rotates to make the rotating member 24 move from the maximum diameter end to the minimum diameter end of the worm wheel track 22, the moving member 25 descends and slides relative to the positioning member 26, and at this time, the positioning member 26 moves to the minimum diameter end of the worm wheel track 22 and slides relative to the limiting member 23, and the covering member 8 descends to cover the supporting platform 3 by the limiting cover 6.

As shown in fig. 1 and 6, as another preferred embodiment of the present invention, the connection unit includes:

the gear 19 is coaxially and fixedly connected with the feeding wheel 2; and

the gear ring 20 is coaxially and fixedly arranged with the transmission piece 21, and the gear ring 20 is meshed with the gear 19.

In one aspect of the present embodiment, the connection unit may be, in addition to the above structure, a gear assembly formed by meshing a plurality of gears, as long as the rotation of the feeding wheel 2 can be achieved to drive the transmission member 21 to rotate, and the connection unit is not limited in the present embodiment.

In practical application, the feeding wheel 2 rotates to drive the gear 19 to rotate, the gear ring 20 is driven to rotate through meshing transmission, and then the transmission member 21 rotates, so that the transmission assembly can drive the capping component 8 to move.

As shown in fig. 1, as another preferred embodiment of the present invention, the lifting assembly includes:

the bearing piece 11 is arranged on the operating platform 1 in a sliding mode, and the bearing piece 11 is connected with the output end of the driving source 13; and

the connecting piece 10 is rotatably arranged on the bearing piece 11, lifting pieces 12 with the same number as that of the bearing tables 3 are arranged on the connecting piece 10, and the connecting piece 10 and the feeding wheel 2 are installed in a sliding mode;

the supporting platform 3 interferes with the motion track of the lifting piece 12, and when the lifting piece 12 is driven to do reciprocating linear motion, the supporting platform 3 is pushed to realize oscillation.

It should be noted that the connecting piece 10 and the bearing piece 11 are both provided with openings for the feeding wheel 2 to pass through, and the bearing piece 11 is rotatably connected with the feeding wheel 2; besides the structure, the lifting assembly can also select components which can realize reciprocating linear motion, such as a screw rod drive and the like driven by a motor, and can realize the pushing of the bearing platform 3.

This embodiment is when practical application, when intermittent type subassembly drive material loading wheel 2 was rotatory, material loading wheel 2 drives the connecting piece 10 rotatory, then relative rotation takes place between connecting piece 10 and the carrier 11, when spacing lid 6 was closed with the cushion cap 3, material loading wheel 2 stopped rotating, power 7 supplied power to driving source 13 this moment, driving source 13 starts the drive and holds carrier 11 and goes up and down, and then drive connecting piece 10 and the lift of a plurality of lifters 12, promote the vibration in order to realize the culture medium of cushion cap 3 through a plurality of lifters 12.

The embodiment of the invention provides shock activation equipment for culturing gibberella, which is convenient to operate, wherein an intermittent assembly drives a feeding wheel 2 to intermittently rotate, so that a plurality of culture mediums can intermittently enter a plurality of supporting platforms 3, after the feeding wheel 2 rotates for a circle, a plurality of limiting covers 6 just cover the supporting platforms 3 to limit the culture mediums respectively, at the moment, a first pole piece 4 and a second pole piece 5 are butted to form a loop, a power supply 7 supplies power to a lifting assembly, the lifting assembly starts to push the supporting platforms 3 and drives the culture mediums to vibrate, and the problem that the shock activation equipment cannot automatically feed the culture mediums and automatically start vibration is effectively avoided.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, and any modifications, equivalents and improvements made within the spirit and principle of the present invention are intended to be included within the scope of the present invention.

Claims (7)

1. A shock activation apparatus for cultivation of gibberella convenient to operate, characterized in that the apparatus comprises:

an operation table;

the feeding wheel is rotatably arranged on the operating platform, a plurality of circumferentially distributed placing positions are arranged on the feeding wheel, and the placing positions are used for placing the bearing platform;

the intermittent assembly is arranged on the operating platform and used for driving the feeding wheel to rotate intermittently so that the plurality of placing positions are sequentially connected with the feeding unit;

the lifting assembly is arranged on the operating platform and is used for driving the plurality of supporting platforms to vibrate;

the covering part is provided with a plurality of limiting covers which respectively correspond to the positions of the bearing platforms; and

the transmission assembly is connected with the feeding wheel, and the feeding wheel can transmit the power of the intermittent assembly to the transmission assembly;

and after the feeding wheel rotates for a circle, the transmission assembly drives the covering piece to move to the plurality of limiting covers to be respectively closed with the plurality of supporting table covers, the first pole piece and the second pole piece are connected into a loop where the power supply and the lifting assembly are located, and the power supply supplies power to the lifting assembly to start the lifting assembly to lift.

2. The easy-to-handle gibberellic fungus cultivation shaking activation apparatus of claim 1, wherein the loading unit comprises:

the feeding hopper is fixed on the operating platform; and

and the feeding pipe is connected with the feeding hopper and used for transporting the culture medium to the placing position.

3. The easy-to-handle gibberellic fungus culturing shake activation apparatus of claim 1, wherein a sealing member for sealing the feeding unit is provided at a position where the sealing member contacts the feeding unit.

4. The easy-to-handle gibberellic fungus cultivation shake activation apparatus of claim 1, wherein the batch assembly comprises:

the driving wheel is rotatably arranged on the operating platform and is driven to rotate by the driving part; and

the driven wheel is coaxially and fixedly connected with the feeding wheel;

fixed columns with the same number as the placing bits are fixed on the driven wheel, and push rods interfering with the movement tracks of the fixed columns are fixed on the driving wheel.

5. The easy-to-operate shock activation apparatus for cultivation of gibberella as claimed in claim 1, wherein the transmission assembly comprises:

the transmission part is provided with a worm wheel rail and is connected with the feeding wheel through a connecting unit;

the limiting piece is fixedly arranged on the operating platform and is rotationally connected with the transmission piece; and

one end of the moving piece is connected with the capping piece, and the other end of the moving piece is rotationally connected with a rotating piece which is slidably arranged on the worm wheel rail;

the movable piece is in sliding fit with the positioning piece which is slidably arranged on the limiting piece.

6. The easy-to-handle gibberellic fungus cultivation shake activation apparatus of claim 5, wherein the connection unit comprises:

the gear is coaxially and fixedly connected with the feeding wheel; and

and the gear ring is coaxially and fixedly installed with the transmission piece, and the gear ring is meshed with the gear.

7. The easy-to-operate shock activation equipment for gibberella culture as claimed in any one of claims 1-6, wherein the lifting assembly comprises:

the bearing piece is arranged on the operating platform in a sliding mode and is connected with the output end of the driving source; and

the connecting piece is rotatably arranged on the bearing piece, lifting pieces with the same number as that of the bearing platforms are arranged on the connecting piece, and the connecting piece is rotatably connected with the feeding wheel;

the bearing platform interferes with the motion trail of the lifting piece, and when the lifting piece is driven to do reciprocating linear motion, the bearing platform can be pushed to realize oscillation.

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