CN113337374A - Microbial fermentation jar air inlet unit - Google Patents

Abstract

The invention discloses an air inlet device of a microbial fermentation tank, which structurally comprises an embedded connecting pipe, an air inlet device and a support, wherein the embedded connecting pipe is embedded and fixedly connected to the left side and the right side of the air inlet device, and the support is movably clamped at the lower end of the air inlet device; air inlet unit is by the absorption frame, purifier, the block frame, the series connection hole is constituteed, absorb frame activity block in purifier upper end, purifier is located block frame upper end, series connection hole riveting is inboard in the block frame, when spraying water smoke in the fermentation cylinder, the moisture that floats in the filter can be absorbed by the sponge piece, and the certain angle of sponge piece to the certain angle of exhaust piece direction slope, make at the adsorbed moisture of sponge piece collect the end discharge along with the weight of self is slow, thereby avoid contacting with the dust in the air.

Description

Microbial fermentation jar air inlet unit

Technical Field

The invention belongs to the technical field of microbial fermentation, and particularly relates to an air inlet device of a microbial fermentation tank.

Background

The microbial fermentation refers to a process of converting raw materials into products required by human beings through a specific metabolic pathway by using microorganisms under a proper condition, and air entering a fermentation tank is purified by using an evolution device in the fermentation process so as to facilitate the fermentation of the microorganisms.

Based on the findings of the inventor, the following defects mainly exist in the prior art, such as: when the microorganism ferments, need the humidity that continuous supplementary moisture kept jar in for water is water smoke form evenly distributed on the fermentation surface, so that when filter equipment filtered gas, its water smoke can float filter equipment in spraying's in-process, and the dust in the air can contact with the hydrone that floats in the filter when leading to filtering, impels the filter to form the bacterial plaque of damp form, thereby can influence the gaseous quality of fermentation cylinder of ventilating.

Therefore, a microbial fermentation tank air inlet device needs to be provided.

Disclosure of Invention

To solve the problems of the above-described technology.

The invention relates to an air inlet device of a microbial fermentation tank, which is realized by the following specific technical means: the structure of the air inlet device comprises an embedded connecting pipe, an air inlet device and a bracket, wherein the embedded connecting pipe is embedded and fixedly connected to the left side and the right side of the air inlet device, and the bracket is movably clamped at the lower end of the air inlet device; the air inlet device is composed of an absorption frame, a purification device, a clamping frame and a series hole, wherein the absorption frame is movably clamped at the upper end of the purification device, the purification device is positioned at the upper end of the clamping frame, and the series hole is riveted and connected to the inner side of the clamping frame.

Wherein, purifier comprises air vent, filtration department, separation hole, adsorption block, the air vent activity joint is in filtration department lower extreme, it is located the adsorption block lower extreme to separate the hole, the adsorption block riveting is connected in filtration department lower extreme, the adsorption block is equipped with two and installs in the air vent left and right sides, and constitutes circular-arcly.

The adsorption block is composed of a flow channel, arc blocks and a collecting tank, the arc blocks are meshed and connected with the right lower end of the flow channel, the collecting tank is movably clamped at the lower end of the flow channel, and the number of the arc blocks is three, and the adsorption block belongs to materials capable of adsorbing moisture.

The discharging block is located on the left side of the sponge block, the supporting block is fixedly connected to the left side of the sponge block in an embedded mode, the sponge block is connected to the inner side of the cavity in a riveted mode, and the sponge block is provided with three cross-mounting portions which are arranged on the inner side of the cavity and inclined towards the discharging block.

The discharge block is composed of a circulation hole, a hollowed-out ring and an outer frame, the circulation hole is movably clamped on the left side of the hollowed-out ring, the hollowed-out ring and the outer frame are of an integrated structure, the circulation hole is dispersedly installed on the left side of the hollowed-out ring, and the inner wall of the circulation hole is smooth.

The collecting groove comprises an inflow groove, a convergence groove, a protruding block and an injection device, the inflow groove is located at the upper left end of the convergence groove, the convergence groove is located between the protruding blocks, the injection device is movably clamped on the right side of the convergence groove, the injection device is in an arc shape and is installed at the bottom end of the convergence groove, and holes are distributed on the inner side of the injection device.

Wherein, injection apparatus comprises triangle piece, annular hole, embedded block, triangle piece welded connection is between the embedded block, the annular hole is located the triangle piece left side, the triangle piece is three horn shapes and installs between the embedded block, and is the rubber material.

The three hornblocks are composed of extrusion blocks, elastic rings, rubber sheets and jet holes, the extrusion blocks are located on the left sides of the elastic rings, the elastic rings are fixedly installed on the inner sides of the left ends of the rubber sheets, the jet holes and the rubber sheets are of an integrated structure, the jet holes are six, and the jet holes are symmetrically distributed at the upper ends and the lower ends of the rubber sheets.

Compared with the prior art, the invention has the following beneficial effects:

1. when spraying water smoke in the fermentation cylinder, the moisture that floats in the filter can be absorbed by the sponge piece, and the certain angle of sponge piece to the block orientation slope of discharging for the moisture that adsorbs at the sponge piece collects the most terminal discharge along with the weight of self is slow, thereby avoids the dust contact with in the air.

2. The extrusion block is extruded through the water droplet that flows in, impels its closed angle department to push up in the elastic ring corner, struts it outwards, and then the water droplet can be followed the hole that is equipped with in the elastic ring and constantly flow into in the sheet rubber, when the water droplet that discharges into the sheet rubber reaches certain weight, can constantly extrude the outer wall, impels it to produce certain deformation and outwards expands, struts the orifice that both ends shrink from top to bottom, impels the rivers of sheet rubber to be the water smoke form from the orifice department of difference and spray in to the fermentation tank once more, so that recycle.

Drawings

FIG. 1 is a schematic structural diagram of an air inlet device of a microbial fermentation tank of the present invention.

FIG. 2 is a schematic structural diagram of an air inlet device of a microbial fermentation tank according to the present invention.

FIG. 3 is a schematic structural diagram of a purification device of a microbial fermentation tank air intake device according to the present invention.

FIG. 4 is a schematic view of an adsorption block of an air inlet device of a microbial fermentation tank.

FIG. 5 is a schematic structural diagram of an arc-shaped block of an air inlet device of a microbial fermentation tank.

FIG. 6 is a schematic view of the discharging block of the inlet device of the microbial fermentation tank.

FIG. 7 is a schematic view of a collecting tank of an air inlet device of a microbial fermentation tank according to the present invention.

FIG. 8 is a schematic structural diagram of an injection device of an air inlet device of a microbial fermentation tank according to the present invention.

FIG. 9 is a schematic structural diagram of a triangular block of an air inlet device of a microbial fermentation tank.

In the figure: the device comprises an embedded connecting pipe-1, an air inlet device-2, a support-3, a suction frame-21, a purifying device-22, a clamping frame-23, a series hole-24, a vent hole-221, a filtering part-222, a separation hole-223, an adsorption block-224, a flow channel-241, an arc block-242, a collecting tank-243, a discharge block-421, a support block-422, a cavity-423, a sponge block-424, a flow hole-211, a hollow ring-212, an outer frame-213, an inflow tank-431, a confluence tank-432, a spraying device-434, a convex block-433, a triangular block-341, an annular hole-342, an embedded block-343, an extrusion block-411, an elastic ring-412, a rubber sheet-413 and a spraying hole-414.

Detailed Description

The invention is further described below with reference to the accompanying drawings:

example 1:

as shown in figures 1 to 6:

the invention provides an air inlet device of a microbial fermentation tank, which structurally comprises an embedded connecting pipe 1, an air inlet device 2 and a support 3, wherein the embedded connecting pipe 1 is embedded and fixedly connected to the left side and the right side of the air inlet device 2, and the support 3 is movably clamped at the lower end of the air inlet device 2; the air inlet device 2 is composed of an absorption frame 21, a purification device 22, a clamping frame 23 and a series hole 24, wherein the absorption frame 21 is movably clamped at the upper end of the purification device 22, the purification device 22 is positioned at the upper end of the clamping frame 23, and the series hole 24 is riveted and connected to the inner side of the clamping frame 23.

The purification device 22 comprises a vent hole 221, a filtering part 222, a separation hole 223 and an adsorption block 224, wherein the vent hole 221 is movably clamped at the lower end of the filtering part 222, the separation hole 223 is positioned at the lower end of the adsorption block 224, the adsorption block 224 is riveted and connected to the lower end of the filtering part 222, and the adsorption block 224 is provided with two blocks which are arranged at the left side and the right side of the vent hole 221 and form an arc shape, so that a certain adsorption force can be effectively increased, and water floating on the surface can be absorbed.

The adsorption blocks 224 are composed of a flow channel 241, arc blocks 242 and a collection groove 243, the arc blocks 242 are connected to the right lower end of the flow channel 241 in an engaged mode, the collection groove 243 is movably clamped at the lower end of the flow channel 241, the arc blocks 242 are three and made of materials capable of adsorbing moisture, and floating water molecules can be adsorbed and conducted to avoid contact with dust.

The arc-shaped block 242 comprises a discharge block 421, a supporting block 422, a cavity 423 and a sponge block 424, the discharge block 421 is located on the left side of the sponge block 424, the supporting block 422 is fixedly connected to the left side of the sponge block 424 in an embedded mode, the sponge block 424 is connected to the inner side of the cavity 423 in a riveted mode, the sponge block 424 is provided with three cross pieces which are installed on the inner side of the cavity 423 and inclined towards the discharge block 421, and when the sponge block 424 reaches a saturation state, water drops slowly collect towards the tail end and then drop to the discharge block 421.

Wherein, the piece 421 of discharging comprises circulation hole 211, fretwork ring 212, frame 213, circulation hole 211 activity joint in fretwork ring 212 left side, fretwork ring 212 and frame 213 are the integral structure, circulation hole 211 is the dispersion form and installs in fretwork ring 212 left side, and the inner wall is comparatively level and smooth, is convenient for the rivers to discharge from different circulation hole 211, and collects to the equidirectional, avoids forming and piles up.

The specific use mode and function of the embodiment are as follows:

when the invention is used, the embedded connecting pipe 1 is connected with fermentation equipment, air is introduced from the suction frame 21 in the air inlet device 2, filtered and purified by the purifying device 22 and then enters the fermentation tank along the holes of the serial holes 24, while the purification device 22 is provided with the adsorption blocks 224 which are symmetrically arranged, when the water mist is sprayed in the fermentation tank, the absorption block 224 is provided with an arc block 242, so that the moisture floating in the filter can be absorbed by the sponge block 424 in the arc block 242, the sponge block 424 inclines to the direction of the discharging block 421 by a certain angle, so that the moisture absorbed by the sponge block 424 is collected to the extreme end along with the slow self weight and discharged, then flows to the hollowed-out ring 212 in the discharging block 421 along the arc-shaped inner contour of the cavity 423, and then is discharged from different flow through holes 211 to the collecting groove 243 at the end of the flow channel 241 for collection, thereby avoiding the dust in the air from contacting.

Example 2:

as shown in fig. 7 to 9:

the collecting tank 243 is composed of an inflow tank 431, a confluence tank 432, protruding blocks 433 and a spraying device 434, wherein the inflow tank 431 is located at the upper left end of the confluence tank 432, the confluence tank 432 is located between the protruding blocks 433, the spraying device 434 is movably clamped on the right side of the confluence tank 432, the spraying device 434 is installed at the bottom end of the confluence tank 432 in an arc shape, holes are distributed on the inner side of the spraying device 434, so that water drops in the confluence tank 432 are continuously converged in the spraying device 434, and then the water drops are sprayed out in a water mist shape through extrusion.

The spraying device 434 is composed of triangular blocks 341, an annular hole 342 and embedded blocks 343, the triangular blocks 341 are welded between the embedded blocks 343, the annular hole 342 is located on the left side of the triangular blocks 341, the triangular blocks 341 are installed between the embedded blocks 343 in a triangular shape and are made of rubber, collected water drops can be conveniently discharged into the bottom ends of the triangular blocks 341, and then the collected water drops can be uniformly sprayed outwards.

The triangular block 341 is composed of an extrusion block 411, an elastic ring 412, a rubber sheet 413 and spray holes 414, the extrusion block 411 is located on the left side of the elastic ring 412, the elastic ring 412 is fixedly installed on the inner side of the left end of the rubber sheet 413, the spray holes 414 and the rubber sheet 413 are of an integrated structure, six spray holes 414 are symmetrically distributed at the upper end and the lower end of the rubber sheet 413, so that when water drops accumulated in the rubber sheet 413 reach a certain degree, the contracted spray holes 414 are opened, and then the water drops are discharged.

The specific use mode and function of the embodiment are as follows:

the water drops discharged from the arc block 242 flow in from the inflow groove 431 in the collecting groove 243, then flow to the spraying device 434 along the converging groove 432, and are gathered to the triangular block 341 through the annular hole 342 arranged in the spraying device 434, along with the increasing of the discharged amount, the inflowing water drops extrude the extrusion block 411 to cause the sharp corner to be propped against the corner of the elastic ring 412 to expand the elastic ring 412 outwards, then the water drops flow into the rubber sheet 413 continuously from the hole arranged in the elastic ring 412, the holes arranged on the elastic ring 412 are concentrated at the middle position and have smaller diameter, so that the backflow of the discharged water drops of the rubber sheet 413 is avoided, when the water drops discharged into the rubber sheet 413 reach a certain weight, the outer wall is continuously extruded to cause the rubber sheet 413 to generate certain deformation and expand outwards, the contracted spray holes 414 at the upper end and the lower end are expanded, the water drops of the rubber sheet 413 are sprayed into the fermentation tank again from different spray holes 414 in a water mist shape, so as to be recycled.

The technical solutions of the present invention or similar technical solutions designed by those skilled in the art based on the teachings of the technical solutions of the present invention are all within the scope of the present invention to achieve the above technical effects.

Claims (8)

1. The air inlet device of the microbial fermentation tank structurally comprises an embedded connecting pipe (1), an air inlet device (2) and a support (3), wherein the embedded connecting pipe (1) is embedded and fixedly connected to the left side and the right side of the air inlet device (2), and the support (3) is movably clamped at the lower end of the air inlet device (2); the method is characterized in that:

the air inlet device (2) is composed of an absorbing frame (21), a purifying device (22), a clamping frame (23) and a series hole (24), wherein the absorbing frame (21) is movably clamped at the upper end of the purifying device (22), the purifying device (22) is positioned at the upper end of the clamping frame (23), and the series hole (24) is riveted and connected to the inner side of the clamping frame (23).

2. The air intake device of the microbial fermentation tank as claimed in claim 1, wherein: the purification device (22) comprises a vent hole (221), a filtering part (222), a separation hole (223) and an adsorption block (224), wherein the vent hole (221) is movably clamped at the lower end of the filtering part (222), the separation hole (223) is positioned at the lower end of the adsorption block (224), and the adsorption block (224) is riveted at the lower end of the filtering part (222).

3. The air intake device of the microbial fermentation tank as claimed in claim 2, wherein: the adsorption block (224) consists of a flow channel (241), an arc block (242) and a collecting groove (243), the arc block (242) is meshed with the right lower end of the flow channel (241), and the collecting groove (243) is movably clamped at the lower end of the flow channel (241).

4. The air intake device of the microbial fermentation tank as claimed in claim 3, wherein: the arc-shaped block (242) is composed of a discharge block (421), a supporting block (422), a cavity (423) and a sponge block (424), the discharge block (421) is located on the left side of the sponge block (424), the supporting block (422) is fixedly connected to the left side of the sponge block (424) in an embedded mode, and the sponge block (424) is connected to the inner side of the cavity (423) in a riveting mode.

5. The air intake device of the microbial fermentation tank as claimed in claim 4, wherein: the discharge block (421) is composed of a circulation hole (211), a hollow ring (212) and an outer frame (213), the circulation hole (211) is movably clamped on the left side of the hollow ring (212), and the hollow ring (212) and the outer frame (213) are of an integrated structure.

6. The air intake device of the microbial fermentation tank as claimed in claim 3, wherein: the collecting groove (243) is composed of an inflow groove (431), a confluence groove (432), protruding blocks (433) and an injection device (434), the inflow groove (431) is located at the left upper end of the confluence groove (432), the confluence groove (432) is located between the protruding blocks (433), and the injection device (434) is movably clamped at the right side of the confluence groove (432).

7. The air intake device of the microbial fermentation tank as claimed in claim 6, wherein: the spraying device (434) is composed of a triangular block (341), an annular hole (342) and an embedded block (343), the triangular block (341) is connected between the embedded blocks (343) in a welding mode, and the annular hole (342) is located on the left side of the triangular block (341).

8. The air intake device of the microbial fermentation tank as claimed in claim 7, wherein: the triangular block (341) is composed of an extrusion block (411), an elastic ring (412), a rubber sheet (413) and an injection hole (414), the extrusion block (411) is located on the left side of the elastic ring (412), the elastic ring (412) is fixedly installed on the inner side of the left end of the rubber sheet (413), and the injection hole (414) and the rubber sheet (413) are of an integrated structure.

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