CN219478751U - Inoculation equipment for solid three-stage bacteria - Google Patents

Abstract

The utility model provides inoculation equipment for solid three-stage bacteria, which belongs to the technical field of edible fungi production equipment and comprises a supporting frame, a material containing disc, a conveying mechanism, a lifting mechanism, a hopper, a plurality of strain containing tubes and a disturbance mechanism; the material containing tray is suitable for containing a plurality of fungus sticks, and the plugging parts of the fungus sticks are arranged upwards; the conveying mechanism is rotatably arranged on the supporting frame and is suitable for circularly and reciprocally conveying the material containing disc towards the discharge end of the conveying mechanism; the lifting mechanism comprises a clamping part; the hopper is positioned above the support frame and is fixed on the support frame through the connecting piece; the bottom of the hopper is provided with a blanking hole; a plurality of strain accommodating pipes are connected to the hopper; the disturbance mechanism is rotatably arranged in the hopper. The plugging part is lifted by the clamping part, and the solid three-level strain is guided by the strain accommodating tube, so that the solid three-level strain can fall into the strain receiving holes of the strain bars, and the strain bar inoculation process is completed; through the above process, the labor force of operators can be reduced, and the production efficiency can be improved.

Description

Inoculation equipment for solid three-stage bacteria

Technical Field

The utility model belongs to the technical field of edible fungi production equipment, and particularly relates to inoculation equipment for solid three-stage bacteria.

Background

In the mushroom cultivation process, holes are required to be punched on the side wall of a mushroom stick, and strains are placed into the holes of the mushroom stick to finish inoculation of the strains; after the inoculation of the fungus sticks is finished, transversely placing the fungus sticks at the designated positions; the strain grows on the fungus stick and finally grows into the mushroom. For the fungus stick of solid tertiary fungus, its tip can reserve and connect the fungus hole to the axis direction of fungus stick sets up. In order to prevent the foreign bacteria from entering the bacteria receiving hole of the bacteria stick, the blocking part is generally filled in the bacteria receiving hole of the bacteria stick.

In the prior art, when inoculating solid tertiary fungus, operating personnel take out the shutoff portion of fungus stick earlier, then put into the fungus hole that connects of fungus stick with solid tertiary fungus. However, in the bacteria inoculation process, the operator is required to take out the plugging part, and then the solid three-stage bacteria can be put into the bacteria inoculation holes of the bacteria stick, so that the labor intensity of the operator can be increased; in the long-time inoculation process, operators can be tired, and then the inoculation efficiency can be affected.

Disclosure of Invention

The embodiment of the utility model provides inoculation equipment for solid three-stage bacteria, and aims to solve the technical problems of high labor intensity and low inoculation efficiency in the process of inoculating the solid three-stage bacteria in the prior art.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

there is provided an inoculation apparatus for solid tertiary bacteria comprising:

a support frame;

the material containing disc is suitable for containing a plurality of fungus sticks, and the plugging parts of the fungus sticks are arranged upwards;

the conveying mechanism is rotatably arranged on the supporting frame and is suitable for circularly and reciprocally conveying the material containing disc towards the discharge end of the conveying mechanism;

the lifting mechanism comprises a plurality of clamping parts which are in one-to-one correspondence with the fungus sticks, and each clamping part is suitable for clamping the plugging part; the clamping part has a degree of freedom suitable for sliding along the height direction so as to pull out the plugging part;

the hopper is positioned above the supporting frame and is fixed on the supporting frame through a connecting piece; the bottom of the hopper is provided with blanking holes which are suitable for being in one-to-one correspondence with the fungus receiving holes of the fungus sticks; the hopper is suitable for containing solid three-stage bacteria;

a plurality of strain accommodating pipes are connected to the hopper; the top end is communicated with the blanking hole, and the bottom end is suitable for being communicated with a fungus receiving hole of a fungus stick; and

the disturbing mechanism is rotatably arranged in the hopper and is suitable for disturbing the solid three-stage bacteria in the hopper so as to enable the solid three-stage bacteria to fall into the bacteria receiving holes of the bacteria stick.

In one possible implementation manner, a connecting plate is horizontally arranged at the bottom of the hopper in a sliding manner, and a fungus dropping area and a plugging area are formed on the connecting plate; the fungus falling area is provided with a plurality of through holes which are in one-to-one correspondence with the fungus falling holes and the fungus accommodating pipes, and the fungus accommodating pipes are fixed on the connecting plate;

the inoculation apparatus further comprises:

the transverse pushing mechanism is connected to the hopper and provided with a transverse pushing end which is suitable for being connected with the connecting plate so as to transversely push the connecting plate, align the strain accommodating tube with the strain receiving hole of the strain rod and simultaneously enable the blocking area of the connecting plate to block the blanking hole of the hopper;

wherein, the bottom of each strain accommodating tube is provided with a sealing plate in a sliding manner, and a plurality of sealing plates are connected through connecting rods; the support frame is provided with a blocking part which is suitable for blocking the connecting rod, so that when the connecting plate slides in place, the strain accommodating tube is aligned with the strain receiving hole of the strain rod, and the sealing plate opens the bottom of the strain accommodating tube.

In one possible implementation, the outer peripheral wall of the strain-accommodating tube has a slide at a position near the bottom, and the slide is horizontally arranged; the sealing plate is in sliding fit with the slide way.

In one possible implementation manner, the sealing plate is provided with an elastic piece, and two ends of the elastic piece are fixedly connected with the sealing plate and the strain accommodating tube respectively;

the sealing plate is suitable for sealing the bottom end of the strain accommodating tube under the action of elastic force of the elastic piece.

In one possible implementation, the inoculation device further comprises:

the fixed plate is positioned above the material containing disc; the fixing plate is fixed on the connecting piece;

the sliding plate is positioned below the fixed plate, and the bottom of the sliding plate is provided with a plurality of push rods which are suitable for being in one-to-one correspondence with the bacteria receiving holes; and

the pushing power piece is arranged on the fixed plate; the pushing end of the pushing power piece penetrates through the fixed plate and is connected with the sliding plate;

wherein when the strain accommodating tube is aligned with the strain receiving hole, the sealing plate opens the bottom of the strain accommodating tube; under the pushing action of the pushing power piece, the pushing rod pushes the solid three-stage bacteria in the bacteria accommodating tube, so that the solid three-stage bacteria enter the bacteria receiving hole of the bacteria rod.

In one possible implementation manner, two sides of the bottom of the hopper are provided with L-shaped limiting plates, and a chute is formed between the two L-shaped limiting plates; the connecting plate is in sliding fit with the sliding groove, and the upper surface of the connecting plate is in contact with the lower surface of the hopper.

In one possible implementation, the top of the support frame is provided with a blanking groove, and the side wall of the support frame is provided with an opening communicated with the blanking groove; the inoculation equipment further comprises a receiving box arranged in the material dropping groove, wherein the receiving box is in a separation state suitable for sliding out of the material dropping groove;

wherein, when the tray is positioned above the material receiving box, the clamping part is suitable for pulling out the plugging part; when the tray slides away from the material receiving box, the clamping part loosens the blocking part, so that the blocking part falls into the material receiving box.

In one possible implementation, the disturbance mechanism includes a fan blade and a driving motor for driving the fan blade to rotate; the top of the hopper is provided with a sealing cover, and the driving motor is arranged on the sealing cover; and an output shaft of the driving motor penetrates through the sealing cover and is connected with the fan blade.

In one possible implementation manner, the conveying mechanism comprises conveying belts arranged at two sides of the material containing disc, and the conveying belts are in running fit with the supporting frame;

the conveyer belt is fixedly provided with a plurality of grid blocking parts which are arranged at intervals, and the grid blocking parts are suitable for crossing the conveyer belt; and limiting parts which are suitable for being lapped on the conveying belt are fixedly arranged on two sides of the material containing disc, and the limiting parts are positioned between two adjacent grid blocking parts.

In the embodiment of the application, when solid three-level strains are inoculated to the fungus sticks, a plurality of fungus sticks are placed on a material containing tray and are generally arranged into a square structure of 3 multiplied by 4; then conveying the material containing disc through a conveying mechanism; before inoculation, the plugging part is clamped by the clamping part, and the plugging part is pulled out of the fungus stick; then the conveying mechanism conveys the tray to the fungus receiving position, and the solid three-stage strain in the hopper can continuously drop downwards through the rotation of the disturbance mechanism in the hopper, and finally the solid three-stage strain drops into the fungus receiving hole of the fungus stick. After the inoculation is finished, the material is conveyed and discharged through a conveying mechanism. In the process that the disturbance mechanism continuously rotates in the hopper, solid three-level strains in the hopper can continuously fall into the strain accommodating tube from the blanking hole and finally fall into the strain receiving hole of the strain rod.

Compared with the prior art, the inoculation equipment for the solid three-level bacteria has the advantages that the blocking part is lifted through the clamping part, the solid three-level bacteria are guided through the bacteria accommodating pipe, the solid three-level bacteria can fall into the bacteria receiving holes of the bacteria sticks, and the bacteria receiving process of the bacteria sticks is completed; through the above process, the labor force of operators can be reduced, and the production efficiency can be improved.

Drawings

FIG. 1 is a schematic diagram of an inoculation device for solid tertiary bacteria according to an embodiment of the present utility model;

FIG. 2 is an enlarged schematic view of portion A of FIG. 1;

FIG. 3 is a schematic diagram of a pulling mechanism of an inoculation device for solid tertiary bacteria according to an embodiment of the present utility model;

FIG. 4 is an enlarged schematic view of portion B of FIG. 3;

FIG. 5 is an enlarged schematic view of portion C of FIG. 3;

FIG. 6 is a schematic view of a connection plate portion of an inoculating device for solid tertiary bacteria according to an embodiment of the present utility model;

fig. 7 is a schematic diagram of a hopper portion of an inoculation apparatus for solid tertiary bacteria according to an embodiment of the present utility model.

Reference numerals illustrate: 1. a support frame; 11. a material dropping groove; 12. an opening; 13. a material receiving box; 2. a material containing disc; 3. a conveying mechanism; 31. a conveyor belt; 32. a grid part; 4. a lifting mechanism; 41. an N-shaped frame; 42. a lifting plate; 421. a bar-shaped groove; 43. a first cylinder; 44. a first clamping plate; 45. a second clamping plate; 46. a second cylinder; 461. an L-shaped rod; 5. a hopper; 51. a connecting piece; 52. a blanking hole; 53. a connecting plate; 531. a fungus dropping area; 532. plugging the area; 54. an L-shaped limiting plate; 55. a cover; 6. a strain accommodating tube; 61. a sealing plate; 62. a connecting rod; 63. a blocking portion; 64. a slideway; 7. a disturbance mechanism; 71. a fan blade; 8. fungus sticks; 81. a blocking part; 9. a third cylinder; 10. a fixing plate; 1001. a sliding plate; 1002. pushing the power piece; 1003. a push rod; 1004. and a fourth cylinder.

Detailed Description

In order to make the technical problems, technical schemes and beneficial effects to be solved more clear, the utility model is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the utility model.

Referring to fig. 1 to 7 together, an inoculation apparatus for three-stage solid bacteria according to the present utility model will now be described. The inoculation equipment for the solid three-level bacteria comprises a supporting frame 1, a material containing disc 2, a conveying mechanism 3, a lifting mechanism 4, a hopper 5, a plurality of bacteria accommodating pipes 6 and a disturbance mechanism 7; the material containing tray 2 is suitable for containing a plurality of fungus sticks 8, and the plugging part 81 of the fungus sticks 8 is arranged upwards; the conveying mechanism 3 is rotatably arranged on the support frame 1, and the conveying mechanism 3 is suitable for circularly and reciprocally conveying the material containing tray 2 towards the discharge end of the conveying mechanism; the lifting mechanism 4 comprises a plurality of clamping parts which are in one-to-one correspondence with the fungus sticks 8, and each clamping part is suitable for clamping the plugging part 81; the holding portion has a degree of freedom suitable for sliding in the height direction to pull out the blocking portion 81; the hopper 5 is positioned above the support frame 1 and is fixed on the support frame 1 through a connecting piece 51; the bottom of the hopper 5 is provided with blanking holes 52 which are suitable for being in one-to-one correspondence with the fungus receiving holes of the fungus sticks 8; the hopper 5 is suitable for containing solid three-stage bacteria; a plurality of strain accommodating pipes 6 are connected to the hopper 5; the top end is communicated with the blanking hole 52, and the bottom end is suitable for being communicated with a fungus receiving hole of the fungus stick 8; the disturbance mechanism 7 is rotatably arranged in the hopper 5 and is suitable for disturbing the solid three-stage bacteria in the hopper 5 so as to enable the solid three-stage bacteria to fall into the bacteria receiving holes of the bacteria stick 8.

In the embodiment of the application, when inoculating solid three-level strains to the fungus sticks 8, a plurality of fungus sticks 8 are placed on the material containing tray 2 and are generally arranged in a 3×4 form; then the material containing disc 2 is conveyed through the conveying mechanism 3; before inoculation, the plugging part 81 is clamped by the clamping part, and the plugging part 81 is pulled out of the fungus stick 8; then the conveying mechanism 3 conveys the material containing tray 2 to a fungus receiving position, and the solid three-level fungus in the hopper 5 can continuously drop downwards through the rotation of the disturbing mechanism 7 in the hopper 5, and finally the solid three-level fungus drops into a fungus receiving hole of the fungus stick 8. After the inoculation is finished, the material is conveyed and discharged through a conveying mechanism 3. During the rotation of the disturbing mechanism 7 in the hopper 5, the solid three-stage strain in the hopper 5 can be dropped into the strain accommodating tube 6 from the blanking hole 52 and finally into the strain receiving hole of the strain rod 8.

Compared with the prior art, the inoculation equipment for the solid three-level bacteria provided by the utility model has the advantages that the blocking part 81 is lifted by the clamping part, and the solid three-level bacteria are guided by the bacteria accommodating pipe 6, so that the solid three-level bacteria can drop into the bacteria receiving holes of the bacteria stick 8, and the bacteria receiving process of the bacteria stick 8 is completed; through the above process, the labor force of operators can be reduced, and the production efficiency can be improved.

It should be noted that, the lifting mechanism 4 and the hopper 5 are both located on the movement path of the tray 2, and during the movement process of the tray 2, the tray 2 passes through the lifting mechanism 4 and then passes through the hopper 5. The lifting mechanism 4 further comprises an N-shaped frame 41, and the N-shaped frame 41 spans the support frame 1; the lifting plate 42 is slidably arranged in the N-shaped frame 41, a first air cylinder 43 is fixedly arranged on the N-shaped frame 41, and a piston rod of the first air cylinder 43 penetrates through the N-shaped frame 41 and is connected with the lifting plate 42. The clamping part is arranged at the bottom of the lifting plate 42 and comprises a first clamping plate 44 and a second clamping plate 45, the first clamping plate 44 is fixed on the lifting plate 42, and the second clamping plate 45 is in sliding fit with the lifting plate 42; the top of the lifting plate 42 is provided with a second air cylinder 46 which is suitable for driving the second clamping plate 45 to slide, the piston rod end of the second air cylinder 46 is fixedly provided with an L-shaped rod 461, and the L-shaped rod 461 penetrates through the lifting plate 42 and is connected with the second clamping plate 45; the lifting plate 42 is provided with a bar-shaped groove 421 for sliding the L-shaped lever 461. The first clamp 44 and the second clamp 45 can clamp the plugging portion 81 by the expansion and contraction of the piston rod of the second cylinder 46, and the plugging portion 81 can be pulled out of the fungus stick 8 by the expansion and contraction of the piston rod of the first cylinder 43. The device is placed in a closed space with a sterilization function, such as a purification workshop, when in use, so that the bacteria on the bacteria stick 8 can be reduced.

In some embodiments, as shown in fig. 1 to 7, a connecting plate 53 is horizontally arranged at the bottom of the hopper 5 in a sliding manner, and a fungus dropping area 531 and a plugging area 532 are arranged on the connecting plate 53; the fungus falling area 531 is provided with a plurality of through holes which are in one-to-one correspondence with the fungus falling holes 52 and the fungus accommodating pipes 6, the fungus accommodating pipes 6 are fixed on the connecting plate 53, and the inoculation equipment also comprises a transverse pushing mechanism; a lateral pushing mechanism is connected to the hopper 5, the lateral pushing mechanism is provided with a lateral pushing end which is suitable for being connected with the connecting plate 53 so as to laterally push the connecting plate 53, align the strain containing tube 6 with the strain receiving hole of the strain rod 8, and simultaneously enable the plugging area 532 of the connecting plate 53 to plug the blanking hole 52 of the hopper 5; wherein, the bottom of each strain accommodating tube 6 is provided with a sealing plate 61 in a sliding manner, and a plurality of sealing plates 61 are connected through a connecting rod 62; the support frame 1 has a blocking portion 63 adapted to block the connecting rod 62 so that when the connecting plate 53 is slid into place, the strain-accommodating tube 6 is aligned with the strain-receiving hole of the strain bar 8, and the sealing plate 61 opens the bottom of the strain-accommodating tube 6.

By providing the fungus dropping area 531 and the plugging area 532 on the connection plate 53, when fungus inoculation is required, the fungus dropping area 531 is aligned with the blanking hole 52 on the hopper 5, and at this time, solid three-level fungus in the hopper 5 can be dropped into the fungus accommodating tube 6; then pushing the connecting plate 53 by a transverse pushing mechanism to enable the blocking area 532 to correspond to the bottom of the hopper 5 so as to block the blanking hole 52 at the bottom of the hopper 5; at this time, the bacteria receiving area of the connection plate 53 corresponds to the bacteria stick 8 on the tray 2. During the sliding of the connection plate 53, the blocking portion 63 of the support frame 1 contacts the connection rod 62 to block the sliding of the connection rod 62; after the connection plate 53 is slid into place, the closing plate 61 can open the strain-accommodating tube 6 so that the solid tertiary strain in the strain-accommodating tube 6 falls into the strain receiving hole of the strain rod 8.

The transverse pushing mechanism comprises a third air cylinder 9, a cylinder body of the third air cylinder 9 is fixed on the hopper 5, a piston rod of the third air cylinder 9 is connected with the connecting plate 53, and the connecting plate 53 can be driven to slide on the hopper 5 through expansion and contraction of the piston rod of the third air cylinder 9.

Illustratively, two sides of the bottom of the hopper 5 are provided with L-shaped limiting plates 54, and a chute is formed between the two L-shaped limiting plates 54; the connection plate 53 is slidably fitted with the chute, and the upper surface of the connection plate 53 is in contact with the lower surface of the hopper 5. The L-shaped limiting plate 54 supports and limits the connecting plate 53, so that the situation that the connecting plate 53 slides away from the hopper 5 can be reduced. In the process that the strain in the strain accommodating tube 6 falls into the strain receiving hole of the strain rod 8, the bottom of the hopper 5 is plugged through the plugging area 532 of the connecting plate 53, so that the condition of material leakage is reduced.

In addition, by arranging the sealing plate 61 at the bottom of the strain accommodating tube 6, when the solid three-stage strain in the hopper 5 falls into the strain accommodating tube 6, the strain leaking from the strain accommodating tube 6 can be reduced, and the waste of the strain can be reduced.

In some embodiments, as shown in fig. 1 to 7, the outer peripheral wall of the seed accommodating tube 6 has a slide 64 near the bottom, the slide 64 being disposed horizontally; the closure plate 61 is in sliding engagement with the slide 64. The sealing plate 61 is provided with an elastic member (not shown in the figure), and two ends of the elastic member are fixedly connected with the sealing plate 61 and the strain accommodating tube 6 respectively; wherein the sealing plate 61 is adapted to seal the bottom end of the strain containing tube 6 under the elastic force of the elastic member.

The elastic member includes a spring, and both ends of the spring are fixedly connected with the sealing plate 61 and the strain accommodating tube 6, respectively; the sealing plate 61 can seal the bottom of the strain containing tube 6 under the action of spring force. The sealing plate 61 is in sliding fit with the slide way 64 on the strain containing tube 6 through the sliding part, so that the sliding direction of the sealing plate 61 can be guided, and in the resetting process of the connecting plate 53, the sealing plate 61 seals the bottom of the strain containing tube 6 under the action of the elastic force of the spring.

In some embodiments, as shown in fig. 1 to 7, the inoculating device further comprises a fixed plate 10, a sliding plate 1001, and a pushing power member 1002; the fixed plate 10 is positioned above the Cheng Liao disk 2; the fixing plate 10 is fixed on the connecting piece 51; the sliding plate 1001 is located below the fixed plate 10, and the bottom of the sliding plate 1001 is provided with a plurality of push rods 1003 which are suitable for being in one-to-one correspondence with the bacteria receiving holes; the pushing power piece 1002 is arranged on the fixed plate 10; the pushing end of the pushing power piece 1002 passes through the fixed plate 10 and is connected with the sliding plate 1001; wherein, when the strain-accommodating tube 6 is aligned with the strain-receiving hole, the sealing plate 61 opens the bottom of the strain-accommodating tube 6; under the pushing action of the pushing power piece 1002, the push rod 1003 pushes solid three-stage bacteria in the bacteria accommodating tube 6 so that the solid three-stage bacteria enter the bacteria receiving hole of the bacteria stick 8.

It should be noted that, the pushing power member 1002 includes a fourth cylinder, a cylinder body of the fourth cylinder is fixed on the fixed plate 10, and a piston rod of the fourth cylinder passes through the fixed plate 10 and is fixedly connected with the sliding plate 1001; when the strain accommodating tube 6 is aligned with the strain receiving hole of the strain rod 8, the piston rod of the fourth cylinder pushes the sliding plate 1001 downwards, so that the push rod 1003 can be inserted into the strain accommodating tube 6, and strain in the strain accommodating tube 6 is pushed into the strain receiving hole of the strain rod 8, thereby being convenient for improving the strain receiving efficiency.

In some embodiments, as shown in fig. 1 to 7, the top of the support frame 1 has a drop chute 11, and the side wall of the support frame 1 has an opening 12 communicating with the drop chute 11; the inoculation device also comprises a material receiving box 13 arranged in the blanking groove 11, wherein the material receiving box 13 has a separation state suitable for sliding out of the blanking groove 11; wherein, when the tray 2 is positioned above the material receiving box 13, the clamping part is suitable for pulling out the plugging part 81; when the tray 2 slides away from the receiving box 13, the clamping portion releases the blocking portion 81 so that the blocking portion 81 falls into the receiving box 13. The conveying mechanism 3 comprises conveying belts 31 arranged on two sides of the material containing disc 2, and the conveying belts 31 are in running fit with the supporting frame 1; a driving motor (not shown in the figure) which is suitable for driving the conveying belt 31 to rotate is fixedly arranged on the supporting frame 1; wherein, the conveyer belt 31 is fixedly provided with a plurality of grid blocking parts 32 which are arranged at intervals, and the grid blocking parts 32 are suitable for crossing the conveyer belt 31; both sides of the material containing disc 2 are fixedly provided with limiting parts which are suitable for being lapped on the conveying belt 31, and the limiting parts are positioned between two adjacent grid blocking parts 32.

It should be noted that, the tray 2 is lapped between the grid blocking parts 32 on the belt through the limiting plate, and the conveying belt 31 can support the tray 2 and drive the tray 2 to move, so as to realize the purpose of conveying materials. When the tray 2 moves above the receiving box 13, the conveyor belt 31 stops rotating, and at this time, the clamping part clamps the plugging part 81 on the fungus stick 8 downwards and pulls out the plugging part 81 after moving upwards; then the conveying belt 31 drives the material containing disc 2 to move to the next station, and at the moment, the material containing disc 2 is positioned right below the push rod 1003; then the strain containing tube 6 on the connection plate 53 slides toward the fungus stick 8, and stops sliding when the strain containing tube 6 is aligned with the fungus receiving hole of the fungus stick 8. When the strain-accommodating tube 6 is aligned with the strain-receiving hole of the strain rod 8, the sealing plate 61 opens the bottom of the strain-accommodating tube 6; the push rod 1003 is downwards inserted into the strain accommodating tube 6, so that the strain in the strain accommodating tube 6 can be pushed into the strain receiving hole of the strain rod 8, and the strain receiving efficiency is improved.

In some embodiments, as shown in fig. 1 to 7, the perturbation mechanism 7 includes a fan blade 71 and a driving motor (not shown in the figures) for driving the fan blade 71 to rotate; the top of the hopper 5 is provided with a sealing cover 55, and a driving motor is arranged on the sealing cover 55; the output shaft of the drive motor passes through the cover 55 and is connected to the fan blade 71.

It should be noted that, the fan blade 71 is driven by the driving motor to rotate, so that the fan blade 71 can play a role in stirring and disturbing the solid three-stage strain, and the solid three-stage strain in the hopper 5 can fall into the strain accommodating tube 6 conveniently. When it is necessary to add solid three-stage strain to hopper 5, lid 55 is opened to allow solid three-stage strain to be placed in hopper 5.

In addition, in order to improve the blanking efficiency, a vibration motor (not shown in the figure) may be provided on the outer side wall of the hopper 5, and the speed of the strain falling in the hopper 5 may be increased by the vibration of the vibration motor.

The foregoing description of the preferred embodiments of the utility model is not intended to be limiting, but rather is intended to cover all modifications, equivalents, and alternatives falling within the spirit and principles of the utility model.

Claims (9)

1. An inoculating device for solid tertiary bacteria, comprising:

a support frame;

the material containing disc is suitable for containing a plurality of fungus sticks, and the plugging parts of the fungus sticks are arranged upwards;

the conveying mechanism is rotatably arranged on the supporting frame and is suitable for circularly and reciprocally conveying the material containing disc towards the discharge end of the conveying mechanism;

the lifting mechanism comprises a plurality of clamping parts which are in one-to-one correspondence with the fungus sticks, and each clamping part is suitable for clamping the plugging part; the clamping part has a degree of freedom suitable for sliding along the height direction so as to pull out the plugging part;

the hopper is positioned above the supporting frame and is fixed on the supporting frame through a connecting piece; the bottom of the hopper is provided with blanking holes which are suitable for being in one-to-one correspondence with the fungus receiving holes of the fungus sticks; the hopper is suitable for containing solid three-stage bacteria;

a plurality of strain accommodating pipes are connected to the hopper; the top end is communicated with the blanking hole, and the bottom end is suitable for being communicated with a fungus receiving hole of a fungus stick; and

the disturbing mechanism is rotatably arranged in the hopper and is suitable for disturbing the solid three-stage bacteria in the hopper so as to enable the solid three-stage bacteria to fall into the bacteria receiving holes of the bacteria stick.

2. The inoculation equipment for solid three-stage bacteria according to claim 1, wherein a connecting plate is horizontally arranged at the bottom of the hopper in a sliding manner, and a bacteria falling area and a plugging area are formed on the connecting plate; the fungus falling area is provided with a plurality of through holes which are in one-to-one correspondence with the fungus falling holes and the fungus accommodating pipes, and the fungus accommodating pipes are fixed on the connecting plate;

the inoculation apparatus further comprises:

the transverse pushing mechanism is connected to the hopper and provided with a transverse pushing end which is suitable for being connected with the connecting plate so as to transversely push the connecting plate, align the strain accommodating tube with the strain receiving hole of the strain rod and simultaneously enable the blocking area of the connecting plate to block the blanking hole of the hopper;

wherein, the bottom of each strain accommodating tube is provided with a sealing plate in a sliding manner, and a plurality of sealing plates are connected through connecting rods; the support frame is provided with a blocking part which is suitable for blocking the connecting rod, so that when the connecting plate slides in place, the strain accommodating tube is aligned with the strain receiving hole of the strain rod, and the sealing plate opens the bottom of the strain accommodating tube.

3. An inoculating device for solid tertiary bacteria according to claim 2, wherein the outer peripheral wall of said bacteria-containing tube has a slide in a position near the bottom, said slide being horizontally disposed; the sealing plate is in sliding fit with the slide way.

4. A device for inoculating solid three-stage bacteria according to claim 3, wherein the sealing plate is provided with an elastic member, and both ends of the elastic member are fixedly connected with the sealing plate and the bacteria accommodating tube respectively;

the sealing plate is suitable for sealing the bottom end of the strain accommodating tube under the action of elastic force of the elastic piece.

5. An inoculating device for solid tertiary bacteria as claimed in claim 2, wherein the inoculating device further comprises:

the fixed plate is positioned above the material containing disc; the fixing plate is fixed on the connecting piece;

the sliding plate is positioned below the fixed plate, and the bottom of the sliding plate is provided with a plurality of push rods which are suitable for being in one-to-one correspondence with the bacteria receiving holes; and

the pushing power piece is arranged on the fixed plate; the pushing end of the pushing power piece penetrates through the fixed plate and is connected with the sliding plate;

wherein when the strain accommodating tube is aligned with the strain receiving hole, the sealing plate opens the bottom of the strain accommodating tube; under the pushing action of the pushing power piece, the pushing rod pushes the solid three-stage bacteria in the bacteria accommodating tube, so that the solid three-stage bacteria enter the bacteria receiving hole of the bacteria rod.

6. The inoculation equipment for solid three-stage bacteria according to claim 2, wherein two sides of the bottom of the hopper are provided with L-shaped limiting plates, and a chute is formed between the two L-shaped limiting plates; the connecting plate is in sliding fit with the sliding groove, and the upper surface of the connecting plate is in contact with the lower surface of the hopper.

7. The inoculating device for solid tertiary bacteria of claim 1 wherein the top of the support frame has a chute and the side walls of the support frame have openings in communication with the chute; the inoculation equipment further comprises a receiving box arranged in the material dropping groove, wherein the receiving box is in a separation state suitable for sliding out of the material dropping groove;

wherein, when the tray is positioned above the material receiving box, the clamping part is suitable for pulling out the plugging part; when the tray slides away from the material receiving box, the clamping part loosens the blocking part, so that the blocking part falls into the material receiving box.

8. The inoculation equipment for solid three-stage bacteria according to claim 7, wherein the conveying mechanism comprises conveying belts arranged on two sides of the material containing tray, and the conveying belts are in rotary fit with the supporting frame;

the conveyer belt is fixedly provided with a plurality of grid blocking parts which are arranged at intervals, and the grid blocking parts are suitable for crossing the conveyer belt; and limiting parts which are suitable for being lapped on the conveying belt are fixedly arranged on two sides of the material containing disc, and the limiting parts are positioned between two adjacent grid blocking parts.

9. The inoculating device for solid three-stage bacteria according to claim 1, wherein the disturbing mechanism comprises fan blades and a driving motor for driving the fan blades to rotate; the top of the hopper is provided with a sealing cover, and the driving motor is arranged on the sealing cover; and an output shaft of the driving motor penetrates through the sealing cover and is connected with the fan blade.