CN110938538A - Biological feed heat preservation fermenting installation - Google Patents

Abstract

The invention discloses a biological feed heat-preservation fermentation device, which comprises supporting legs, a fermentation assembly, a window, a stirring assembly, a discharge port, a PLC (programmable logic controller) and an electric control cabinet, wherein the stirring assembly is arranged, a driving motor drives a rotary rod to rotate, and the stirring rod stirs materials in a fermentation tank, so that the materials in the fermentation tank are evenly stirred, the fermentation efficiency of the biological feed is ensured, a scraper plate is attached to the inner wall of the fermentation tank to move, the materials attached to the inner wall of the fermentation tank are scraped, and the phenomenon that the materials are caked on the inner wall of the fermentation tank is avoided; through setting up the fermentation subassembly, temperature sensor detects the temperature value in the fermentation cylinder, and when the temperature value reached the lower limit value of setting, PLC controller control solenoid valve opened, carries steam to heat the fermentation cylinder toward the intermediate layer of fermentation cylinder in, when detecting the temperature value and reaching the upper limit value of setting for, PLC controller control solenoid valve closed, makes the temperature value in the fermentation cylinder be in suitable scope, reaches the purpose of accurate control fermentation temperature.

Description

Biological feed heat preservation fermenting installation

Technical Field

The invention relates to the technical field of biological feed fermentation, in particular to a biological feed heat-preservation fermentation device.

Background

The microbial fermentation refers to a process of converting raw materials into products required by human beings through a specific metabolic pathway under a proper condition by using microorganisms, the production level of the microbial fermentation mainly depends on the genetic characteristics and culture conditions of strains, the application range of fermentation engineering, the pharmaceutical industry, the food industry, the energy industry, the chemical industry, the aspects of agriculture, plant gene modification, biological nitrogen fixation, engineering insecticidal bacteria and biological pesticides, microbial nutrients, environmental protection and the like, the conventional biological feed fermentation device is inconvenient for stirring materials, so that the materials are not uniformly mixed, the fermentation efficiency of biological feed is influenced, and therefore, a biological feed heat-preservation fermentation device is urgently needed to solve the problems and is convenient for market popularization and application.

The stirring operation of material is not convenient for carry out by current biological feed fermenting installation, makes the material mix inhomogeneous, influences biological feed's fermentation efficiency, is not convenient for carry out the control of fermenting installation internal temperature, is unfavorable for the problem of the fermentation quality of accuse biological feed.

Disclosure of Invention

Technical problem to be solved

Aiming at the defects of the prior art, the invention provides a biological feed heat-preservation fermentation device, which solves the problems that the conventional biological feed fermentation device is inconvenient for stirring operation of materials, so that the materials are not uniformly mixed, the fermentation efficiency of biological feed is influenced, the temperature in the fermentation device is inconvenient to control, and the fermentation quality of the biological feed is not favorable to control.

(II) technical scheme

In order to achieve the purpose, the invention provides the following technical scheme: a biological feed heat-preservation fermentation device comprises four supporting legs, a fermentation assembly, a window, a stirring assembly, a discharge port, a PLC (programmable logic controller) and an electric control cabinet, wherein the supporting legs are fixed at four corners below the fermentation assembly through bolts and are cylindrical; the window is embedded in the middle of the front side of the fermentation assembly; the discharge port is welded in the middle position below the fermentation assembly and is provided with a valve plate, and the discharge port is communicated with the interior of the fermentation assembly; the stirring assembly is fixed in the middle position above the fermentation assembly through a bolt and penetrates into the fermentation assembly; the PLC is fixed below the left side of the fermentation assembly through a bolt and is connected with the electric control cabinet through a lead, and the PLC is FX1S-30 MR-001; the electric control cabinet is fixed below the right side of the fermentation assembly through bolts and is connected with the commercial power through a wire.

The fermentation assembly comprises a fermentation tank, a feed inlet, a temperature sensor, a steam inlet, a steam outlet, a water outlet, a heat preservation layer, a material guide plate and an electromagnetic valve, wherein an interlayer is arranged on the inner wall of the fermentation tank; the two feeding ports are welded on the left side and the right side of the fermentation tank, and the feeding ports are communicated with the interior of the fermentation assembly; the temperature sensor is fixed on the left side above the interior of the fermentation tank through a bolt, and is positioned on the left side between the feed inlets; the steam inlet is welded on the left side of the fermentation tank and communicated with the interlayer of the fermentation tank; the steam outlet is welded on the right side of the fermentation tank and communicated with the interlayer of the fermentation tank; the electromagnetic valve is fixed on the steam inlet through a bolt; the water outlet is welded on the right side below the fermentation tank and is communicated with the interlayer of the fermentation tank; the material guide plate is fixed below the interior of the fermentation tank through bolts; the heat-insulating layer is fixed on the outer side of the fermentation tank through a counter bore bolt.

The feed inlet is provided with a rotary cover; the temperature sensor is respectively connected with the PLC and the electric control cabinet through wires, and the temperature sensor is CWDZ11 type; the steam inlet is connected with a steam source; the steam outlet and the water outlet are both provided with valves; the heat-insulating layer is made of a ceramic fiber blanket material; the cross section of the material guide plate is conical, and the thickness of the inner side of the material guide plate is smaller than that of the outer side of the material guide plate; the electromagnetic valve is respectively connected with the PLC and the electric control cabinet through wires and is of a 2W-320-32K type.

The stirring assembly comprises a driving motor, a rotating rod, a stirring rod and a scraper, the driving motor is fixed in the middle position above the fermentation tank through a bolt, and an output shaft of the driving motor penetrates into the fermentation tank; the rotary rod is fixed below the output shaft of the driving motor through a coupler; the stirring rods are multiple and are fixed on the left side and the right side of the rotary rod through bolts; the scraper plates are multiple and are fixed at the tail end of the stirring rod through counter bore bolts.

The driving motor is respectively connected with the electric control cabinet and the PLC through wires and is in a 130ST-M15015 type; the rotary rod is in a square column shape; the stirring rod is cylindrical; the outer side of the scraper is arc-shaped, and the outer side of the scraper is attached to the inner wall of the fermentation tank.

(III) advantageous effects

The invention provides a biological feed heat-preservation fermentation device. The method has the following beneficial effects:

(1) according to the invention, the stirring assembly is arranged, the driving motor drives the rotary rod to rotate, the stirring rod stirs materials in the fermentation tank, so that the materials in the fermentation tank are uniformly stirred, the fermentation efficiency of the biological feed is ensured, the scraper plate is attached to the inner wall of the fermentation tank to move, the materials attached to the inner wall of the fermentation tank are scraped, the phenomenon that the materials are caked on the inner wall of the fermentation tank is avoided, and the stirring effect of the stirring assembly is improved.

(2) According to the invention, the fermentation assembly is arranged, the temperature sensor detects the temperature value in the fermentation tank, when the temperature value reaches a set lower limit value, the PLC controls the electromagnetic valve to be opened, steam is conveyed into the interlayer of the fermentation tank to heat the fermentation tank, and when the detected temperature value reaches a set upper limit value, the PLC controls the electromagnetic valve to be closed, so that the temperature value in the fermentation tank is in a proper range, the purpose of accurately controlling the fermentation temperature is achieved, and the fermentation quality of the biological feed is controlled.

(3) According to the invention, the heat preservation layer and the material guide plate are arranged, the heat preservation layer is used for preserving heat of the fermentation tank, the heating efficiency of steam is improved, the operation cost of the fermentation device is further reduced, the material guide plate plays a role in guiding materials in the fermentation tank, the materials in the fermentation tank are ensured to be smoothly discharged from the discharge hole, and the production efficiency of biological feed is improved.

Drawings

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a schematic view of the structure of the fermentation module of the present invention;

FIG. 3 is a schematic structural view of a stirring assembly of the present invention;

fig. 4 is a circuit diagram of a PLC controller of the present invention.

In the figure: 1 supporting legs, 2 fermentation subassemblies, 21 fermentation cylinder, 22 feed inlets, 23 temperature sensor, 24 steam inlet, 25 steam outlet, 26 outlet, 27 heat preservation, 28 stock guide, 29 solenoid valve, 3 windows, 4 stirring subassemblies, 41 driving motor, 42 swing arms, 43 puddler, 44 scraper blades, 5 discharge gates, 6PLC controller, 7 automatically controlled cabinets.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Example 1

As shown in fig. 1 to 4, the present invention provides a technical solution: a biological feed heat-preservation fermentation device comprises four supporting legs, a fermentation assembly, a window, a stirring assembly, a discharge port, a PLC (programmable logic controller) and an electric control cabinet, wherein the supporting legs are fixed at four corners below the fermentation assembly through bolts and are cylindrical; the window is embedded in the middle of the front side of the fermentation assembly; the discharge port is welded in the middle position below the fermentation assembly and is provided with a valve plate, and the discharge port is communicated with the interior of the fermentation assembly; the stirring assembly is fixed in the middle position above the fermentation assembly through a bolt and penetrates into the fermentation assembly; the PLC is fixed below the left side of the fermentation assembly through a bolt and is connected with the electric control cabinet through a lead, and the PLC is FX1S-30 MR-001; the electric control cabinet is fixed below the right side of the fermentation assembly through bolts and is connected with the commercial power through a wire.

Example 2

A biological feed heat-preservation fermentation device comprises four supporting legs, a fermentation assembly, a window, a stirring assembly, a discharge port, a PLC (programmable logic controller) and an electric control cabinet, wherein the supporting legs are fixed at four corners below the fermentation assembly through bolts and are cylindrical; the window is embedded in the middle of the front side of the fermentation assembly; the discharge port is welded in the middle position below the fermentation assembly and is provided with a valve plate, and the discharge port is communicated with the interior of the fermentation assembly; the stirring assembly is fixed in the middle position above the fermentation assembly through a bolt and penetrates into the fermentation assembly; the PLC is fixed below the left side of the fermentation assembly through a bolt and is connected with the electric control cabinet through a lead, and the PLC is FX1S-30 MR-001; the electric control cabinet is fixed below the right side of the fermentation assembly through bolts and is connected with the commercial power through a wire.

Preferably, the fermentation assembly comprises a fermentation tank, a feed inlet, a temperature sensor, a steam inlet, a steam outlet, a water outlet, a heat insulation layer, a material guide plate and an electromagnetic valve, wherein an interlayer is arranged on the inner wall of the fermentation tank; the two feeding ports are welded on the left side and the right side of the fermentation tank, and the feeding ports are communicated with the interior of the fermentation assembly; the temperature sensor is fixed on the left side above the interior of the fermentation tank through a bolt, and is positioned on the left side between the feed inlets; the steam inlet is welded on the left side of the fermentation tank and communicated with the interlayer of the fermentation tank; the steam outlet is welded on the right side of the fermentation tank and communicated with the interlayer of the fermentation tank; the electromagnetic valve is fixed on the steam inlet through a bolt; the water outlet is welded on the right side below the fermentation tank and is communicated with the interlayer of the fermentation tank; the material guide plate is fixed below the interior of the fermentation tank through bolts; the heat-insulating layer is fixed on the outer side of the fermentation tank through a counter bore bolt.

Preferably, the feed inlet is provided with a rotary cover; the temperature sensor is respectively connected with the PLC and the electric control cabinet through wires, and the temperature sensor is CWDZ11 type; the steam inlet is connected with a steam source; the steam outlet and the water outlet are both provided with valves; the heat-insulating layer is made of a ceramic fiber blanket material; the cross section of the material guide plate is conical, and the thickness of the inner side of the material guide plate is smaller than that of the outer side of the material guide plate; the electromagnetic valve is respectively connected with the PLC and the electric control cabinet through wires and is of a 2W-320-32K type.

Example 3

A biological feed heat-preservation fermentation device comprises four supporting legs, a fermentation assembly, a window, a stirring assembly, a discharge port, a PLC (programmable logic controller) and an electric control cabinet, wherein the supporting legs are fixed at four corners below the fermentation assembly through bolts and are cylindrical; the window is embedded in the middle of the front side of the fermentation assembly; the discharge port is welded in the middle position below the fermentation assembly and is provided with a valve plate, and the discharge port is communicated with the interior of the fermentation assembly; the stirring assembly is fixed in the middle position above the fermentation assembly through a bolt and penetrates into the fermentation assembly; the PLC is fixed below the left side of the fermentation assembly through a bolt and is connected with the electric control cabinet through a lead, and the PLC is FX1S-30 MR-001; the electric control cabinet is fixed below the right side of the fermentation assembly through bolts and is connected with the commercial power through a wire.

Preferably, the stirring assembly comprises a driving motor, a rotating rod, a stirring rod and a scraper, the driving motor is fixed in the middle position above the fermentation tank through a bolt, and an output shaft of the driving motor penetrates into the fermentation tank; the rotary rod is fixed below the output shaft of the driving motor through a coupler; the stirring rods are multiple and are fixed on the left side and the right side of the rotary rod through bolts; the scraper plates are multiple and are fixed at the tail end of the stirring rod through counter bore bolts.

Preferably, the driving motor is respectively connected with the electric control cabinet and the PLC controller through wires, and the driving motor is of a 130ST-M15015 type; the rotary rod is in a square column shape; the stirring rod is cylindrical; the outer side of the scraper is arc-shaped, and the outer side of the scraper is attached to the inner wall of the fermentation tank.

Example 4

The electric control cabinet 7 is connected with commercial power to supply power, the PLC 6 is electrified to operate to carry out system control, a screw cap of the feed inlet 5 is opened, materials are added into the fermentation tank 21, the screw cap of the feed inlet 5 is covered, the driving motor 41 drives the screw rod 42 to rotate, the stirring rod 43 stirs the materials in the fermentation tank 21, the materials in the fermentation tank 21 are evenly stirred, the fermentation efficiency of the biological feed is ensured, the scraper plate 44 is attached to the inner wall of the fermentation tank 21 to move, the materials attached to the inner wall of the fermentation tank 21 are scraped, the phenomenon that the materials are caked on the inner wall of the fermentation tank 21 is avoided, the stirring effect of the stirring assembly 4 is improved, the temperature sensor 23 detects the temperature value in the fermentation tank 21, when the temperature value reaches a set lower limit value, the PLC 6 controls the electromagnetic valve 29 to be opened, steam is conveyed into an interlayer of the fermentation tank 21 to heat the, PLC 6 control solenoid valve 29 closes, makes the temperature value in fermentation cylinder 21 be in suitable scope, reaches the purpose of accurate control fermentation temperature, is favorable to the fermentation quality of accuse biological fodder, and heat preservation 27 keeps warm fermentation cylinder 21, improves the heating efficiency of steam, and then reduces fermenting installation's running cost, and stock guide 28 plays the guide effect to material in the fermentation cylinder 21, guarantees that the material in the fermentation cylinder 21 is discharged from discharge gate 5 smoothly, improves biological fodder's production efficiency.

To sum up and to obtain, this biological fodder heat preservation fermenting installation includes supporting legs 1 through the setting, fermentation subassembly 2, window 3, stirring subassembly 4, discharge gate 5, PLC controller 6 and automatically controlled cabinet 7, has solved the stirring operation that current biological fodder fermenting installation is not convenient for carry out the material, makes the material mix inhomogeneous, influences the fermentation efficiency of biological fodder, is not convenient for carry out the control of fermenting installation internal temperature, is unfavorable for the problem of the fermentation quality of accuse biological fodder.

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

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (5)

1. The utility model provides a biological feed heat preservation fermenting installation which characterized in that: the biological feed heat-preservation fermentation device comprises four supporting legs (1), a fermentation assembly (2), a window (3), a stirring assembly (4), a discharge hole (5), a PLC (programmable logic controller) and an electric control cabinet (7), wherein the supporting legs (1) are fixed at four corners below the fermentation assembly (2) through bolts, and the supporting legs (1) are cylindrical; the window (3) is embedded in the middle of the front side of the fermentation assembly (2); the discharge port (5) is welded in the middle position below the fermentation assembly (2), the discharge port (5) is provided with a valve plate, and the discharge port (5) is communicated with the interior of the fermentation assembly (2); the stirring assembly (4) is fixed at the middle position above the fermentation assembly (2) through a bolt, and the stirring assembly (4) penetrates into the fermentation assembly (2); the PLC controller (6) is fixed below the left side of the fermentation assembly (2) through a bolt, and the PLC controller (6) is connected with the electric control cabinet (7) through a wire; the electric control cabinet (7) is fixed below the right side of the fermentation assembly (2) through bolts, and the electric control cabinet (7) is connected with a mains supply through a wire.

2. The biological feed heat-preservation fermentation device according to claim 1, characterized in that: the fermentation assembly (2) comprises a fermentation tank (21), a feeding hole (22), a temperature sensor (23), a steam inlet (24), a steam outlet (25), a water outlet (26), a heat insulation layer (27), a material guide plate (28) and an electromagnetic valve (29), wherein an interlayer is arranged on the inner wall of the fermentation tank (21); the number of the feed inlets (22) is two, the feed inlets (22) are welded at the left side and the right side of the fermentation tank (21), and the feed inlets (22) are communicated with the interior of the fermentation assembly (2); the temperature sensor (23) is fixed on the left side above the inside of the fermentation tank (21) through a bolt, and the temperature sensor (23) is positioned on the left side between the feeding holes (22); the steam inlet (24) is welded at the left side of the fermentation tank (21), and the steam inlet (24) is communicated with the interlayer of the fermentation tank (21); the steam outlet (25) is welded at the right side of the fermentation tank (21), and the steam outlet (25) is communicated with the interlayer of the fermentation tank (21); the electromagnetic valve (29) is fixed on the steam inlet (24) through a bolt; the water outlet (26) is welded at the right side below the fermentation tank (21), and the water outlet (26) is communicated with the interlayer of the fermentation tank (21); the material guide plate (28) is fixed below the interior of the fermentation tank (21) through bolts; the heat-insulating layer (27) is fixed on the outer side of the fermentation tank (21) through a counter bore bolt.

3. The biological feed heat-preservation fermentation device according to claim 2, characterized in that: the feed inlet (22) is provided with a rotary cover; the temperature sensor (23) is respectively connected with the PLC (6) and the electric control cabinet (7) through wires; the steam inlet (24) is connected with a steam source; the steam outlet (25) and the water outlet (26) are both provided with valves; the heat-insulating layer (27) is made of a ceramic fiber blanket material; the cross section of the material guide plate (28) is conical, and the thickness of the inner side of the material guide plate (28) is smaller than that of the outer side of the material guide plate; the electromagnetic valve (29) is respectively connected with the PLC controller (6) and the electric control cabinet (7) through wires.

4. The biological feed heat-preservation fermentation device according to claim 1, characterized in that: the stirring assembly (4) comprises a driving motor (41), a rotary rod (42), a stirring rod (43) and a scraper (44), the driving motor (41) is fixed in the middle position above the fermentation tank (21) through a bolt, and an output shaft of the driving motor (41) penetrates into the fermentation tank (21); the rotary rod (42) is fixed below an output shaft of the driving motor (41) through a coupler; the stirring rods (43) are multiple, and the stirring rods (43) are fixed on the left side and the right side of the rotary rod (42) through bolts; the scraping plates (44) are multiple, and the scraping plates (44) are fixed at the tail ends of the stirring rods (43) through counter bore bolts.

5. The biological feed heat-preservation fermentation device according to claim 4, characterized in that: the driving motor (41) is respectively connected with the electric control cabinet (7) and the PLC (6) through wires; the rotary rod (42) is in a square column shape; the stirring rod (43) is cylindrical; the outer side of the scraper (44) is arc-shaped, and the outer side of the scraper (44) is attached to the inner wall of the fermentation tank (21).

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