CN113545299A

CN113545299A - Microbial fermentation bed

Info

Publication number: CN113545299A
Application number: CN202110823068.XA
Authority: CN
Inventors: 雷群益
Original assignee: Individual
Current assignee: Guangzhou Dihuan Bio Environmental Technology Co ltd
Priority date: 2021-07-21
Filing date: 2021-07-21
Publication date: 2021-10-26
Anticipated expiration: 2041-07-21
Also published as: CN113545299B

Abstract

The invention discloses a microbial fermentation bed, which structurally comprises: the invention realizes the operation effect of combining the bottom lining plate with the mud groove sac cavity bed block and forming cultivated organisms on the top of the transverse plate of the treading type trigger base in the mud groove bed body through the propeller truss and the spring wire sac groove, so that the soil level frequency in the greenhouse of the microbial fermentation bed is efficiently overturned, the microbial oxidative degradation efficiency and the illumination cultivation efficiency are improved, the stable development of the organisms in the cultivation greenhouse is improved, the safety of an ecological system balance framework is promoted, and the effect of promoting the growth of the organisms such as chickens and pigs in the biological cultivation greenhouse by microbial fermentation is ensured.

Description

Microbial fermentation bed

Technical Field

The invention relates to a microbial fermentation bed, and belongs to the field of microbes.

Background

The microbes such as the chicken, duck, pig and the like in the livestock shed need to be matched with microbial fermentation to produce soil nutrient components and degrade soil wastes to form a microbial ecosystem circulating operation effect, and the microbial fermentation bed has the cultivation high efficiency of the breeding of the greenhouse organisms, and the defects of the prior art which are public and need to be optimized are as follows:

the biological cultivation greenhouse of the fermentation bed is matched with the microbial soil fermentation operation to form the nutrition supply and waste degradation operation effects of the ecological environment, but the conventional fermentation bed needs to regularly turn the soil in the greenhouse to ensure the illumination absorption and oxidation ventilation of the microbes, drives the organisms in the fermentation bed to be stored, carries other microbes to enter the fermentation bed to easily damage the ecological system, and carries the foreign flora organisms to easily cause diseases to the cultivated organisms.

Disclosure of Invention

Aiming at the defects in the prior art, the invention aims to provide a microbial fermentation bed to solve the problems that a biological cultivation greenhouse of the fermentation bed is matched with microbial soil fermentation operation to form nutrition supply and waste degradation operation effects of an ecological environment, but the conventional fermentation bed needs to regularly perform soil turning operation in the greenhouse to ensure illumination absorption and oxidation ventilation of microbes, the organisms in the fermentation bed are driven to be stored and then carry other microbes into the fermentation bed to easily damage an ecological system, and the introduced foreign flora organisms easily cause diseases to cultivated organisms.

In order to achieve the purpose, the invention is realized by the following technical scheme: a microbial fermentation bed structurally comprises: end liner plate, mud groove bag chamber bed piece, wallboard piece, vent, grid strut frame, mud groove bag chamber bed piece nestification is on the top surface of end liner plate and be in same horizontal plane, the wallboard piece is equipped with two and inserts both sides around mud groove bag chamber bed piece respectively, the wallboard piece is nested integrative and be in same vertical face with the vent, grid strut frame inserts on the top of embedding mud groove bag chamber bed piece, mud groove bag chamber bed piece is equipped with propeller truss, spring silk bag groove, the mud groove bed body, propeller truss installs in the inside in spring silk bag groove, propeller truss inserts with spring silk bag groove and inlays integrative and the axle center collineation, the spring silk bag groove is installed in the inside of mud groove bed body, the spring silk bag groove adopts clearance fit with the mud groove bed body, the mud groove bed body nestification is on the top surface of end liner plate and is in same horizontal plane.

In order to optimize the technical scheme, the method further comprises the following steps:

as a further improvement of the invention, the propeller truss consists of two shifting plates and a transverse shaft rod, wherein the two shifting plates are respectively arranged at the left side and the right side of the transverse shaft rod, and the shifting plates and the transverse shaft rod are inserted and embedded into a whole and are mutually vertical.

As a further improvement of the invention, the shifting plate is composed of a soil-turning propeller plate and a shifting block, the shifting block is arranged inside the soil-turning propeller plate, and the soil-turning propeller plate and the shifting block are inserted and embedded together and are perpendicular to each other.

As a further improvement of the invention, the spring wire bag groove is composed of two air box cushion blocks and a cross-shaped torsion spring bag, the two air box cushion blocks are respectively arranged at the upper side and the lower side of the cross-shaped torsion spring bag, the air box cushion blocks and the cross-shaped torsion spring bag are buckled together, and the axes of the air box cushion blocks and the cross-shaped torsion spring bag are collinear.

As a further improvement of the invention, the air box cushion block consists of an air box trough plate and a torsion spring pipe, wherein the torsion spring pipe is arranged inside the air box trough plate, and the air box trough plate and the torsion spring pipe are nested into a whole and are perpendicular to each other.

As a further improvement of the invention, the bottom lining plate consists of a clamping plate wheel groove and a base transverse plate, the clamping plate wheel groove is arranged on the top of the base transverse plate, and the clamping plate wheel groove and the base transverse plate are buckled together and are positioned on the same horizontal plane.

As a further improvement of the invention, the clamping plate wheel groove consists of a wheel disc groove and a clamping plate frame, the clamping plate frame is arranged inside the wheel disc groove, and the wheel disc groove and the clamping plate frame are nested into a whole and are positioned on the same vertical plane.

As a further improvement of the invention, the wallboard block consists of a press-buckling block and a wallboard body, wherein the press-buckling block is arranged below the bottom of the wallboard body, and the press-buckling block and the wallboard body are buckled together and are positioned on the same vertical plane.

As a further improvement of the invention, the buckle pressing block is composed of a pressing plate block and a buckle belt block, the buckle belt block is installed inside the pressing plate block, and the pressing plate block and the buckle belt block are buckled together and are perpendicular to each other.

As a further improvement of the invention, the plectrum cushion block is a composite sheet structure with a protruding plectrum plate at the front end and a circular cushion disc at the rear side, so that the small-amplitude fluidized bed linkage operation effect of the microbial fermentation bed can be conveniently formed by linkage of the sheet frame soil turning and the propeller.

As a further improvement of the invention, the air box groove plate is of a blast plate groove structure with narrow-band air box blade plate bag grooves in the middle of upper and lower widths, so that the subsequent pressure bearing is facilitated to form the operation effects of upper and lower extrusion and transverse blast outward expansion.

As a further improvement of the invention, the clamping plate frame is of a composite plate frame structure with quarter-leaf plates inserted with double thin rods at the upper part and the lower part, so that the assembly operation effect of the base of the fermentation bed formed by matching the bottom edges of the upper pull buckle and the lower pull buckle is facilitated.

As a further improvement of the invention, the buckle belt block is a composite buckle part structure with the upper and lower buckle blocks and the middle pull buckle rod inserted with the belt, so that the wall panel can be conveniently clamped up and down to form the stability operation effect of integral building joggle insertion.

Advantageous effects

According to the microbial fermentation bed, workers enable the clamping plate wheel grooves of the bottom lining plates to be in tension buckling with the mud groove bed bodies of mud groove bag cavity bed blocks through the wheel disc grooves and the clamping plate frames at the top of the transverse plate of the base, wall plate blocks and ventilation openings form wall plate frame windproof and ventilation operation effects on the front side and the rear side of the grid support rod frame, subsequent livestock-raising organisms are enabled to be movable in a shed to prevent wind and rain, the ventilation environment in the shed is matched with that animals tread soil in the shed to promote wind box cushion blocks of the wind box bag grooves to press cross torsional spring bags to link the wind box groove plates and the torsional spring pipes to form a spring wire twisting operation effect of extruding the transverse shaft of a propeller truss up and down, the soil turning propeller plates and the shifting plate assisting the soil turning cushion blocks to improve the operation effect of microbial oxidative decomposition and sunlight absorption propagation, and the ecological environment degradation of wastes in the shed and nutrient solution of the fermentation bed are facilitated to provide operation effects.

The invention has the following advantages after operation:

the application end liner plate cooperatees with mud groove bag chamber bed piece, form the pedal formula of breeding biology at the internal mud groove bed through the propeller truss with the spring silk bag groove and trigger base diaphragm top and turn over native operation effect, it is high-efficient to let soil level frequency upset in the big-arch shelter of microbial fermentation bed, and promote microbial oxidation degradation efficiency and illumination cultivation efficiency, promote the stable development of breeding the biology in the big-arch shelter, promote the security of ecosystem balance framework, guarantee microbial fermentation to the biology formation promotion growth effect such as chicken of biological breeding big-arch shelter, pigs.

Drawings

Other features, objects, and advantages of the present invention will become more apparent from the following detailed description of the embodiments of the invention when taken in conjunction with the accompanying drawings, in which:

FIG. 1 is a schematic structural diagram of a microbial fermentation bed according to the present invention.

FIG. 2 is a detailed sectional structure diagram of the bottom lining plate and the mud groove bag cavity bed block of the invention.

FIG. 3 is a detailed sectional structure diagram of the mud trough pocket bed block and the wall plate block of the present invention.

FIG. 4 is a detailed sectional structure diagram of the mud groove bag cavity bed block, the propeller truss and the spring bag groove.

Fig. 5 is a cross-sectional enlarged structural view of the working state of the cleat wheel groove of the present invention.

Fig. 6 is a schematic cross-sectional enlarged structure view of the snap-fastener block in the working state of the present invention.

FIG. 7 is an enlarged cross-sectional view of the striking plate according to the present invention.

FIG. 8 is an enlarged sectional view schematically showing the operation of the bellows spacer of the present invention.

Description of reference numerals: bottom lining plate-1, mud groove bag cavity bed block-2, wall plate block-3, ventilation opening-4, grid brace rod frame-5, propeller truss-2A, spring bag groove-2B, mud groove bed body-2C, plectrum plate-2A 1, cross shaft rod-2A 2, soil turning propeller plate-2A 11, plectrum pad-2A 12, bellows pad-2B 1, cross torsion spring bag-2B 2, bellows groove plate-2B 11, torsion spring tube-2B 12, clamping plate wheel groove-11, base transverse plate-12, wheel groove-111, clamping plate frame-112, pressing buckle block-31, wall plate body-32, pressing plate block-311 and buckle belt block-312.

Detailed Description

In order to make the technical means, the creation characteristics, the achievement purposes and the effects of the invention easy to understand, the invention is further described with the specific embodiments.

The first embodiment is as follows:

referring to fig. 1 to 8, the present invention provides a microbial fermentation bed, which comprises: the mud groove air sac bed comprises a bottom lining plate 1, a mud groove air sac bed block 2, wall plate blocks 3, ventilation openings 4 and a grid support rod frame 5, wherein the mud groove air sac bed block 2 is nested on the top surface of the bottom lining plate 1 and is positioned on the same horizontal plane, the wall plate blocks 3 are provided with two parts which are respectively inserted and embedded in the front side and the rear side of the mud groove air sac bed block 2, the wall plate blocks 3 and the ventilation openings 4 are nested into a whole and are positioned on the same vertical plane, the grid support rod frame 5 is inserted and embedded on the top of the mud groove air sac bed block 2, the mud groove air sac bed block 2 is provided with a rotary propeller truss 2A, a reed wire air sac groove 2B and a mud groove bed body 2C, the rotary propeller truss 2A is installed in a reed wire air sac groove 2B, the rotary propeller truss 2A and the reed wire air sac groove 2B are inserted and embedded into a whole and are collinear, the reed wire sac groove 2B is installed in the mud groove bed body 2C, and the reed wire sac groove bed body 2B is in clearance fit with the mud groove bed body 2C, the mud groove bed body 2C is nested on the top surface of the bottom lining plate 1 and is positioned on the same horizontal plane.

Referring to fig. 4, the propeller truss 2A is composed of two paddle plates 2A1 and a horizontal shaft rod 2A2, the two paddle plates 2A1 are respectively installed at the left and right sides of the horizontal shaft rod 2A2, the two paddle plates 2A1 and the horizontal shaft rod 2A2 are inserted and embedded into a whole and are perpendicular to each other, the spring capsule groove 2B is composed of a bellows cushion block 2B1 and a cross-shaped torsion spring capsule 2B2, the two bellows cushion blocks 2B1 are respectively installed at the upper and lower sides of the cross-shaped torsion spring capsule 2B2, the bellows cushion block 2B1 and the cross-shaped torsion spring capsule 2B2 are buckled together and have collinear axes, and the cross-shaped torsion spring capsule 2B2 is matched with the horizontal shaft rod 2A2 to form an integral pull-type cross-shaped rotation operation effect, so as to improve the up-down-left-right linkage soil-turning operation effect of the up-down propeller.

Referring to fig. 7, the paddle board 2a1 is composed of a soil turning propeller board 2a11 and a paddle pad block 2a12, the paddle pad block 2a12 is installed inside the soil turning propeller board 2a11, the soil turning propeller board 2a11 and the paddle pad block 2a12 are inserted and embedded together and are perpendicular to each other, the paddle pad block 2a12 is a composite sheet structure with a protruding paddle board at the front end and a circular pad at the rear side, so that the sheet frame soil turning is linked with a propeller to form a small-amplitude fluid bed linkage operation effect of the microbial fermentation bed, and the soil turning propeller board 2a11 and the paddle pad block 2a12 are perpendicular to each other to shovel soil to form a soil fluid bed material turning operation effect of the microbial fermentation bed.

Referring to fig. 8, the bellows cushion block 2B1 is composed of a bellows slot plate 2B11 and a torsion spring tube 2B12, the torsion spring tube 2B12 is installed inside the bellows slot plate 2B11, the bellows slot plate 2B11 and the torsion spring tube 2B12 are nested and integrated and perpendicular to each other, the bellows slot plate 2B11 is a blast plate slot structure with a narrow-band bellows blade plate slot in the middle of an upper wide and a lower wide, so that the operation effect of vertical extrusion and lateral blast expansion is conveniently formed by subsequent pressure bearing, and the deformation and return operation effect of load-bearing extrusion is formed by the bellows slot plate 2B11 and the torsion spring tube 2B 12.

Referring to fig. 2, the bottom lining plate 1 is composed of a clamping plate wheel groove 11 and a base transverse plate 12, the clamping plate wheel groove 11 is installed on the top of the base transverse plate 12, the clamping plate wheel groove 11 and the base transverse plate 12 are buckled together and are located on the same horizontal plane, and the clamping plate wheel groove 11 is buckled on the top of the base transverse plate 12 to form an integral lining operation effect.

Referring to fig. 5, the clamping plate wheel slot 11 is composed of a wheel slot 111 and a clamping plate frame 112, the clamping plate frame 112 is installed inside the wheel slot 111, the wheel slot 111 and the clamping plate frame 112 are nested into a whole and are located on the same vertical plane, the clamping plate frame 112 is a composite plate frame structure with upper and lower quarter-leaf plates inserted with double thin rods, the upper and lower pull buckles are convenient to assist in matching the bottom edge to form a base assembling operation effect of the fermentation bed, and the clamping plate frame 112 is pulled through the wheel slot 111 to form an operation effect of assisting in clamping and preventing tripping.

The working process is as follows: the worker pulls the clamping plate wheel groove 11 of the bottom lining plate 1 on the top of the base transverse plate 12 through the wheel disc groove 111 and the clamping plate frame 112 to buckle the mud groove bed body 2C of the mud groove bag cavity bed block 2, so that the wall plate block 3 and the ventilation opening 4 form the wall plate frame windproof and ventilation operation effects on the front side and the rear side of the grid strut bar frame 5, and the subsequent livestock-raising organisms can actively prevent wind and rain in the shed, and the ventilation environment in the shed is matched with the soil of animals to tread in the shed to promote the cross torsion spring bag 2B2 to press the air box cushion 2B1 of the spring bag groove 2B up and down, so that the cross torsion spring bag 2B2 is linked with the air box groove plate 2B11 and the torsion spring pipe 2B12 to form a spring wire twisting operation effect of up and down extrusion on the transverse shaft rod 2A2 of the propeller truss 2A, so that the soil turning propeller plate 2A11 and the shifting pad 2A12 of the shifting plate 2A1 assist in soil turning to improve the operation effect of microbial oxidative decomposition and sunlight absorption propagation, and the ecological environment is convenient to degrade wastes in the shed and nutrient solution of the fermentation bed to provide the operation effect.

Example two:

referring to FIGS. 1 to 8, the present invention provides a microbial fermentation bed, which is otherwise the same as in example 1 except that:

referring to fig. 3, the wallboard block 3 is composed of a press-fastening block 31 and a wallboard body 32, the press-fastening block 31 is installed under the bottom of the wallboard body 32, the press-fastening block 31 and the wallboard body 32 are fastened together and are located on the same vertical plane, and a joggle wall body reinforcing operation effect is formed at the bottom of the wallboard body 32 through the press-fastening block 31.

Referring to fig. 6, the press-fastening block 31 is composed of a press plate block 311 and a fastening belt block 312, the fastening belt block 312 is installed inside the press plate block 311, the press plate block 311 and the fastening belt block 312 are fastened together and perpendicular to each other, the fastening belt block 312 is a composite fastening member structure in which fastening rods penetrate through strips in upper and lower belt fastening blocks, so that the wallboard can be conveniently clamped up and down to form a stable operation effect of mortise penetration of the whole building, and an operation effect borne by upper and lower tension fasteners is formed by the press plate block 311 and the fastening belt block 312.

The wall body of building the poultry big-arch shelter through the staff needs to form the bottom building reinforcing operation effect through the plate pressing block 311 and the buckle belt block 312 that erect wallboard body 32 with wallboard block 3 and cooperate the buckle block 31, lets follow-up low-order microbial fermentation bed soil horizon cooperation biological cultivation cultivate the promotion nutrition absorption and the discarded object degradation operation effect that forms ecosystem.

The invention achieves the effect of using the bottom lining plate 1 to be matched with the mud groove sac cavity bed block 2, forming the treading type trigger base transverse plate 12 top soil turning operation of the cultured organisms in the mud groove bed body 2C through the propeller truss 2A and the spring sac groove 2B, enabling the soil level frequency in the greenhouse of the microbial fermentation bed to be efficiently turned, improving the microbial oxidation degradation efficiency and the illumination cultivation efficiency, improving the stable development of the organisms in the cultivation greenhouse, promoting the safety of the ecological system balance framework, ensuring the microbial fermentation to form the growth promoting effect on the organisms such as chickens and pigs in the biological cultivation greenhouse, so as to solve the problem that the biological cultivation greenhouse of the fermentation bed is matched with the microbial soil fermentation operation to form the nutrition supply and waste degradation operation effect of the ecological environment regularly, but the conventional fermentation bed needs to carry out soil turning operation in the greenhouse to ensure the illumination absorption and oxidation ventilation of the microorganisms, the biological driving and storing place in the fermentation bed is carried with other microorganisms to enter the fermentation bed, which is easy to destroy the ecological system, and the carried impurity flora organisms are easy to cause diseases to the cultured organisms.

The specific embodiments described herein are merely illustrative of the invention. Various modifications or additions may be made to the described embodiments or alternatives may be employed by those skilled in the art without departing from the scope of the invention or exceeding the scope of the claims appended hereto.

Claims

1. A microbial fermentation bed structurally comprises: end backing plate (1), mud groove bag chamber bed piece (2), wallboard piece (3), vent (4), grid strut frame (5), its characterized in that:

the mud groove sac cavity bed blocks (2) are nested on the top surface of the bottom lining plate (1), two wallboard blocks (3) are arranged and are respectively inserted and embedded on the front side and the rear side of the mud groove sac cavity bed blocks (2), the wallboard blocks (3) and the ventilation openings (4) are nested into a whole, and the grid support rod frame (5) is inserted and embedded on the top of the mud groove sac cavity bed blocks (2);

the mud groove sac cavity bed block (2) is provided with a propeller truss (2A), a spring wire sac groove (2B) and a mud groove bed body (2C);

the utility model discloses a mud-jack, including the mud-jack bed body, the mud-jack bed body is characterized in that the internal in spring wire bag groove (2B) is installed in oar-rotating truss (2A), the oar-rotating truss (2A) is inserted with spring wire bag groove (2B) and is inlayed integratively, the inside in mud-jack bed body (2C) is installed in spring wire bag groove (2B), spring wire bag groove (2B) cooperatees with the mud-jack bed body (2C), the mud-jack bed body (2C) nests on the top surface of end liner board (1).

2. A microbial fermentation bed according to claim 1, wherein: the propeller truss (2A) is composed of two shifting plates (2A1) and a transverse shaft rod (2A2), the two shifting plates (2A1) are respectively installed on the left side and the right side of the transverse shaft rod (2A2), and the shifting plates (2A1) and the transverse shaft rod (2A2) are inserted and embedded into a whole.

3. A microbial fermentation bed according to claim 2, wherein: the blade shifting plate (2A1) is composed of a soil turning propeller plate (2A11) and a blade shifting cushion block (2A12), the blade shifting cushion block (2A12) is installed inside the soil turning propeller plate (2A11), and the soil turning propeller plate (2A11) and the blade shifting cushion block (2A12) are inserted and embedded together.

4. A microbial fermentation bed according to claim 1, wherein: the spring wire bag groove (2B) is composed of two air box cushion blocks (2B1) and a cross torsion spring bag (2B2), the two air box cushion blocks (2B1) are arranged on the upper side and the lower side of the cross torsion spring bag (2B2) respectively, and the air box cushion blocks (2B1) and the cross torsion spring bag (2B2) are buckled together.

5. A microbial fermentation bed according to claim 4, wherein: the air box cushion block (2B1) is composed of an air box groove plate (2B11) and a torsion spring pipe (2B12), the torsion spring pipe (2B12) is installed inside the air box groove plate (2B11), and the air box groove plate (2B11) and the torsion spring pipe (2B12) are nested into a whole.

6. A microbial fermentation bed according to claim 1, wherein: bottom liner (1) comprises splint race (11), base diaphragm (12), install on the top of base diaphragm (12) splint race (11), splint race (11) are in the same place with base diaphragm (12) lock.

7. A microbial fermentation bed according to claim 6, wherein: splint race (11) comprise rim plate groove (111), splint frame (112), install in the inside of rim plate groove (111) splint frame (112), rim plate groove (111) and splint frame (112) are nested integratively.

8. A microbial fermentation bed according to claim 1, wherein: the wallboard block (3) comprises a press buckle block (31) and a wallboard body (32), the press buckle block (31) is installed below the bottom of the wallboard body (32), and the press buckle block (31) is buckled with the wallboard body (32) together.

9. A microbial fermentation bed according to claim 8, wherein: the buckle pressing block (31) is composed of a pressing plate block (311) and a buckle belt block (312), the buckle belt block (312) is installed inside the pressing plate block (311), and the pressing plate block (311) is buckled with the buckle belt block (312) together.