CN219239653U - Yellow storage feed fermentation microbial inoculum adder - Google Patents

Abstract

The utility model discloses a yellow storage feed fermentation bacteria agent adder, which comprises moving devices which are arranged in parallel, wherein lifters are arranged on the moving devices, a distribution main pipe is transversely connected between the lifters, a plurality of insertion pipes are arranged at intervals at the bottom of the distribution main pipe, the bottom ends of the insertion pipes are provided with pointed ends and are closed, and a plurality of layers of spraying holes are arranged along the same height as the peripheral wall of the insertion pipe; the cannula is communicated with the distribution main pipe, and the distribution main pipe is communicated with the dosing pump through a hose. After the insertion pipe is inserted into the raw material of the yellow storage feed, the microbial inoculum enters the raw material of the yellow storage feed from the spraying holes, and the spraying holes are arranged in a multi-layer manner, so that the raw material of the yellow storage feed can be divided into a plurality of layers for spraying, the microbial inoculum is distributed more uniformly, the insertion pipe is lifted after the spraying is finished, then the platform trolley is controlled to move for a certain distance, and the insertion pipe is inserted into the raw material of the yellow storage feed for spraying, so that the microbial inoculum is distributed in the horizontal direction through water absorption and permeation.

Description

Yellow storage feed fermentation microbial inoculum adder

Technical Field

The utility model relates to a microbial inoculum adder, in particular to a microbial inoculum adder for yellow storage feed fermentation.

Background

When the yellow fodder is made, corn stalk is crushed with a crushing and kneading machine, pressed and then placed into a fermentation tank, and water and composite microbial inoculum are sprayed on the crushed stalk. As the microbial inoculum is sprayed from the surface, the compressed straw and the like have stronger filterability, so that most microbial inoculum is trapped on the surface and the middle part, and the microbial inoculum at the bottom is less distributed, thereby influencing the normal fermentation process.

Disclosure of Invention

The utility model aims to solve the technical problem of providing a fermenting bacteria agent adder for yellow storage, which can add fermenting bacteria agent from inside layer by layer, and avoid bacteria agent from being trapped on the surface of straw of yellow storage.

In order to solve the technical problems, the technical scheme of the utility model is as follows:

the feeder comprises moving devices which are arranged in parallel, lifters are arranged on the moving devices, a distribution main pipe is transversely connected between the lifters, a plurality of insertion pipes are arranged at intervals at the bottom of the distribution main pipe, the bottom ends of the insertion pipes are provided with pointed ends and are closed, and a plurality of layers of spraying holes are formed along the same height of the peripheral wall of each insertion pipe; the cannula is communicated with the distribution main pipe, and the distribution main pipe is communicated with the dosing pump through a hose.

Further, the moving devices all adopt platform trolleys which all run along tracks arranged in parallel.

Further, the lifter adopts a synchronous belt lifting device, the synchronous belt lifting device comprises a sliding frame, sliding grooves are formed in the inner side of the sliding frame, a driven belt pulley and a driving belt pulley are respectively arranged at the top and the bottom of the sliding grooves, a synchronous belt is arranged between the driven belt pulley and the driving belt pulley, a sliding block running along the sliding grooves is fixed on the synchronous belt, the driving belt pulley is connected with a stepping motor for driving, and two ends of a distribution main pipe are respectively connected with the sliding blocks.

Further, one end of the distribution header pipe is vertically connected with a pipe joint.

Furthermore, the intubation tube adopts a rectangular flat tube.

Further, an upper limit travel switch and a lower limit travel switch are respectively arranged on the side edge of the sliding groove on the sliding frame, and the lower limit travel switch can move up and down along the arranged clamping rail.

Furthermore, a cross rod is further arranged between the bottoms of the sliding frames, and limiting sleeves are arranged at positions, corresponding to the insertion tubes, on the cross rod.

By adopting the technical scheme, after the insertion pipe is inserted into the raw material of the yellow storage feed, the dosing pump starts to work, the microbial inoculum enters the raw material of the yellow storage feed from the spraying holes, and the spraying holes are arranged in a multi-layer mode, so that the raw material of the yellow storage feed can be divided into a plurality of layers to be sprayed, the microbial inoculum is distributed more uniformly, the insertion pipe is lifted after the spraying is completed, then the platform trolley is controlled to move for a certain distance, the insertion pipe is inserted into the raw material of the yellow storage feed to spray, and the raw material of the yellow storage feed is mostly straw and the like, so that the microbial inoculum is strong in water absorption, and can be distributed in the horizontal direction through water absorption and permeation.

Drawings

FIG. 1 is a schematic perspective view of the present utility model;

fig. 2 is an enlarged schematic view of a portion a in fig. 1.

In the figure, the device comprises a 1-platform trolley, a 11-track, a 2-lifter, a 21-carriage, a 22-chute, a 23-driven belt wheel, a 24-stepping motor, a 25-synchronous belt, a 26-upper limit travel switch, a 27-lower limit travel switch, a 271-clamping rail, a 3-distribution main pipe, a 31-pipe joint, a 32-sliding block, a 4-insertion pipe, a 41-spraying hole and a 42-tip.

Detailed Description

The following describes the embodiments of the present utility model further with reference to the drawings. The description of these embodiments is provided to assist understanding of the present utility model, but is not intended to limit the present utility model. In addition, the technical features of the embodiments of the present utility model described below may be combined with each other as long as they do not collide with each other.

As shown in fig. 1-2:

the utility model provides a yellow fodder zymophyte agent adder, at first includes parallel arrangement's mobile device, and mobile device can adopt platform dolly 1, and parallel installation track 11 respectively in the both sides of fermentation vat, and platform dolly 1 is along prescribing the motion, all installs lift 2 on platform dolly 1, transversely is connected with distribution house steward 3 between the lift 2, distribution house steward 3 bottom interval is installed a plurality of intubates 4, intubate 4 bottom all is equipped with pointed end 42 and seals, sets up the spraying hole 41 of a plurality of layers along intubate 4 week wall equal altitude; the cannula 4 is communicated with the distribution header pipe 3, and the distribution header pipe 3 is communicated with the dosing pump through a hose.

The movement of the platform trolley 1 is used for controlling the horizontal movement of the insertion pipe 4, the lifting device 2 is used for controlling the vertical movement of the insertion pipe 4, after the raw materials full of yellow storage feed are paved in the fermentation tank, the platform trolley 1 is controlled to move to one end of the fermentation tank, the lifting device 2 is controlled to move downwards, the lifting device 2 adopts the synchronous belt 25 lifting device, the lifting device 25 is better and lower in height because the lifting device adopts the synchronous belt 25 to lift the platform trolley because the lifting device adopts a hydraulic cylinder or the like to drive the platform trolley to be higher, the sliding groove 22 is formed in the inner side of the sliding frame 21, the driven pulleys 23 and the driving pulleys are respectively arranged at the top and the bottom of the sliding groove 22, the synchronous belt 25 is arranged between the driven pulleys 23 and the driving pulleys, the sliding blocks 32 running along the sliding groove 22 are fixedly arranged on the synchronous belt 25, the driving pulleys are connected with the main pipe step motor 24 to drive, the two ends of the main distribution pipe 3 are respectively connected with the sliding blocks 32, the distribution 3 can be pressed downwards or upwards by utilizing the limit of the sliding blocks 32 and the sliding groove 22, and the height of the main pipe 24 can be controlled stably and accurately.

After the insertion pipe 4 is inserted into the raw material of the yellow storage, the dosing pump starts to work, the microbial inoculum enters the raw material of the yellow storage from the spraying holes 41, and the spraying holes 41 are arranged in a multi-layer mode, so that the raw material of the yellow storage can be divided into a plurality of layers to be sprayed, the microbial inoculum is distributed more uniformly, the insertion pipe 4 is lifted after the spraying is finished, then the platform trolley 1 is controlled to move for a certain distance, the insertion pipe 4 is inserted into the raw material of the yellow storage to be sprayed, and the raw material of the yellow storage is mostly straw and the like, so that the microbial inoculum is highly hydroscopically absorbed, and the distribution of the microbial inoculum can be completed in the horizontal direction through water absorption and permeation.

In order to facilitate the connection between the distribution manifold 3 and the hose, a pipe joint 31 may be vertically connected to one end of the distribution manifold 3 for connecting the hose, and the cannula 4 is preferably a rectangular flat tube, so that the resistance is relatively small during insertion.

In order to match with automatic control, an upper limit travel switch 26 and a lower limit travel switch 27 may be respectively disposed on the side edge of the sliding chute 22 on the sliding frame 21, and the lower limit travel switch 27 may move up and down along the disposed clamping rail 271, so as to perform lower travel positioning by changing the position of the lower limit travel switch 27, so that real-time automatic control can be facilitated, and manual control is not required (the circuit principle that the travel switch is used for automatically controlling the start and stop of the motor belongs to the prior art, so that the description is omitted).

A cross bar can be arranged between the bottoms of the sliding frames 21, and limiting sleeves are arranged on the cross bar corresponding to the positions of the insertion tubes 4, so that the insertion tubes 4 can be prevented from swinging when descending.

The embodiments of the present utility model have been described in detail above with reference to the accompanying drawings, but the present utility model is not limited to the described embodiments. It will be apparent to those skilled in the art that various changes, modifications, substitutions and alterations can be made to these embodiments without departing from the principles and spirit of the utility model, and yet fall within the scope of the utility model.

Claims (7)

1. A yellow storage fodder zymophyte agent adder which is characterized in that: the device comprises moving devices which are arranged in parallel, wherein the moving devices are provided with lifters, a distribution main pipe is transversely connected between the lifters, a plurality of insertion pipes are arranged at intervals at the bottom of the distribution main pipe, the bottom ends of the insertion pipes are provided with tips and are sealed, and a plurality of layers of spraying holes are formed along the same height of the peripheral wall of each insertion pipe; the cannula is communicated with the distribution main pipe, and the distribution main pipe is communicated with the dosing pump through a hose.

2. The silage fermenting bacteria agent adder according to claim 1, characterized in that: the moving devices all adopt platform trolleys, and the platform trolleys all run along tracks which are arranged in parallel.

3. The silage fermenting bacteria agent adder according to claim 2, characterized in that: the lifting device comprises a sliding frame, sliding grooves are formed in the inner side of the sliding frame, a driven belt pulley and a driving belt pulley are respectively arranged at the top and the bottom of the sliding grooves, a synchronous belt is arranged between the driven belt pulley and the driving belt pulley, a sliding block running along the sliding grooves is fixed on the synchronous belt, the driving belt pulley is connected with a stepping motor for driving, and two ends of a distribution main pipe are respectively connected with the sliding block.

4. A silage fermenting bacteria agent adder according to claim 3, characterized in that: one end of the distribution header pipe is vertically connected with a pipe joint.

5. The silage fermenting bacteria agent adder according to claim 1, characterized in that: the intubation tube adopts a rectangular flat tube.

6. A silage fermenting bacteria agent adder according to claim 3, characterized in that: the sliding frame is characterized in that an upper limit travel switch and a lower limit travel switch are respectively arranged on the sliding frame at the side edge of the sliding groove, and the lower limit travel switch can move up and down along the arranged clamping rail.

7. A silage fermenting bacteria agent adder according to claim 3, characterized in that: and a cross rod is further arranged between the bottoms of the sliding frames, and limiting sleeves are arranged at positions, corresponding to the insertion tubes, on the cross rod.

Images