CN211035412U - Biochemical reaction device - Google Patents

Abstract

The utility model discloses a biochemical reaction device, its structure includes the biochemical reaction main part, the feed inlet, direct current motor, seal board and stock chest, the utility model discloses a surface has set up pre-reaction unit in biochemical reaction main part left side upper end, the user is at the inside fermentation bacterial that adds of reaction inner chamber, then add water, open the hot plate after that, through the knob on the second control panel, the temperature that the adjustment is fit for the fermentation, when the fermentation is accomplished, discharge mechanism is opened to the accessible, pour the fermentation bacterial into the biochemical reaction main part inside and carry out the fermentation reaction with organic waste, thereby reached the pre-fermentation bacterial, accelerate the fermentation speed of fermentation bacterial, improve the effect of whole organic waste's fermentation efficiency.

Description

Biochemical reaction device

Technical Field

The utility model relates to a biochemical reaction technical field, concretely relates to biochemical reaction device.

Background

The organic waste refers to solid, liquid or gaseous organic substances and substances generated in production, living and other activities, which lose their original utilization value or are discarded or abandoned without losing their utilization value, and thus, it is necessary to use a biochemical reaction apparatus to perform fermentation of the organic waste to further utilize resources.

When the existing biochemical reaction device is used for fermenting organic wastes, fermentation strains are usually directly placed in the device, the activity of the strains which are placed for the first time is not high, further strain culture is needed, the activity of the strains is improved, but the fermentation time of the strains is long, so that the fermentation time of the organic wastes is increased, and the working efficiency is low.

SUMMERY OF THE UTILITY MODEL

Technical problem to be solved

In order to overcome the defects of the prior art, the biochemical reaction device is provided, the problems that the activity of strains put in for the first time is not high, the strains need to be further cultured, the activity of the strains is improved, but the fermentation time of the strains is long, so that the fermentation time of organic waste is prolonged, and the working efficiency is low are solved, the strains are fermented in advance, the fermentation speed of the fermentation strains is increased, and the fermentation efficiency of the whole organic waste is improved.

(II) technical scheme

The utility model discloses a following technical scheme realizes: the utility model provides a biochemical reaction device, including biochemical reaction main part, feed inlet, direct current motor, seal board, stock chest and pre-reaction device, the feed inlet has been seted up on biochemical reaction main part top right side, biochemical reaction main part top middle part is provided with direct current motor, the direct current motor lower extreme rotates and is connected with the puddler, seal board rear end and biochemical reaction main part plug-in connection to seal board and the symmetrical installation of lower extreme stock chest, stock chest rear end and biochemical reaction main part plug-in connection, biochemical reaction main part front end left side lower extreme is provided with first control panel, the inside first power cord that is provided with of first control panel, direct current motor carries out the electricity with first control panel and is connected, pre-reaction device installs in biochemical reaction main part left side upper end surface, pre-reaction device is by reaction shell, pre-reaction device, A top cover, a reaction inner cavity, a heating plate, a second control panel, a second power line, a discharging mechanism, a discharging port and a hinge, the right end of the reaction shell is welded and fixed with the biochemical reaction main body, the top cover is arranged at the upper end of the reaction shell, the rear end of the top cover is connected with the reaction shell in a turnover way through a hinge, the reaction inner cavity is arranged in the reaction shell, the heating plate is spliced and connected with the left side of the reaction inner cavity, the second control panel is connected with the middle part of the left end of the reaction shell through a bolt, the second power line is arranged in the second control panel, the discharging mechanism is arranged at the lower end of the right side of the reaction inner cavity, the discharging port is arranged at the lower end of the right side of the reaction inner cavity, and the right end of the discharge port extends through the upper end of the left side of the biochemical reaction main body, the hinge is rotatably connected to the upper end of the rear side of the reaction shell, and the heating plate is electrically connected with the second control panel.

Further, discharge mechanism comprises twist grip, sealing washer, gland and apopore, twist grip left end and gland welded fastening, the sealing washer encircles in gland right-hand member surface, the gland right-hand member runs through reaction shell lower extreme right side to the gland left end carries out plug-in connection with reaction inner chamber left end downside, the surface of gland is seted up to the apopore equidistance.

Furthermore, small convex blocks are arranged on the left side and the right side of the lower end of the top cover, and the small convex blocks of the top cover are in plug-in connection with the grooves formed in the left side and the right side of the upper end of the reaction shell.

Further, the heating plate may perform heating of 0 ° to 65 ° or more, and the entire heating plate may have a rectangular parallelepiped shape.

Further, the reaction inner cavity is set to be integrated, and a waterproof layer is arranged at the bottom end of the reaction inner cavity.

Further, two hinges are symmetrically arranged, and the hinges can rotate for 180 degrees.

Furthermore, the water outlet holes are seven, and the overall diameter of each water outlet hole is 2 CM.

Furthermore, the outer surface of the rotating handle is provided with an anti-skidding sleeve, and the handle grip of the rotating handle is designed to be in a shape fitting with the hand of a user.

Further, the model of the dc motor is S86B L130-430.

Furthermore, the sealing ring is made of a fluorine rubber material.

(III) advantageous effects

Compared with the prior art, the utility model, following beneficial effect has:

in order to solve the problem that the activity of the strains put in for the first time is not high, further strain culture is needed, the activity of the strains is improved, but the fermentation time of the strains is long, so that the fermentation time of organic waste is increased, the working efficiency is low, a pre-reaction device is arranged on the outer surface of the upper end of the left side of a biochemical reaction main body, a user adds the fermentation strains into a reaction inner cavity, then water is added, then a heating plate is opened, a knob on a second control panel is used for adjusting the temperature suitable for fermentation, when the fermentation is completed, a discharging mechanism can be opened through the pre-reaction device, the fermentation strains are poured into the biochemical reaction main body to perform fermentation reaction with the organic waste, so that the pre-fermentation strains are reached, the fermentation speed of the fermentation strains is accelerated.

Drawings

Other features, objects and advantages of the invention will become more apparent upon reading of the detailed description of non-limiting embodiments with reference to the following drawings:

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

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

FIG. 3 is a schematic view of the internal structure of the pre-reaction apparatus of the present invention;

FIG. 4 is a schematic view of the pre-reaction device according to the present invention;

fig. 5 is a schematic structural view of the discharging mechanism of the pre-reaction device of the present invention.

In the figure: the biochemical reaction device comprises a biochemical reaction main body-1, a feed inlet-2, a direct current motor-3, a sealing plate-4, a storage tank-5, a first control panel-6, a first power line-7, a stirring rod-8, a pre-reaction device-9, a reaction shell-91, a top cover-92, a reaction inner cavity-93, a heating plate-94, a second control panel-95, a second power line-96, a discharging mechanism-97, a discharge outlet-98, a hinge-99, a rotating handle-971, a sealing ring-972, a sealing pipe-973 and a water outlet-974.

Detailed Description

Referring to fig. 1, fig. 2, fig. 3, fig. 4 and fig. 5, the present invention provides a biochemical reaction apparatus: the biochemical reaction device comprises a biochemical reaction main body 1, a feed inlet 2, a direct current motor 3, a sealing plate 4, a storage tank 5 and a pre-reaction device 9, wherein the feed inlet 2 is formed in the right side of the top end of the biochemical reaction main body 1, the direct current motor 3 is arranged in the middle of the top end of the biochemical reaction main body 1, a stirring rod 8 is connected to the lower end of the direct current motor 3 in a rotating mode, the rear end of the sealing plate 4 is connected with the biochemical reaction main body 1 in a plugging mode, the sealing plate 4 and the storage tank 5 at the lower end are symmetrically installed, the rear end of the storage tank 5 is connected with the biochemical reaction main body 1 in a plugging mode, a first control panel 6 is arranged at the lower end of the left side of the front end of the biochemical reaction main body 1, a first power wire 7 is arranged inside the first control panel 6, the direct current motor, A reaction cavity 93, a heating plate 94, a second control panel 95, a second power line 96, a discharging mechanism 97, a discharging port 98 and a hinge 99, wherein the right end of the reaction shell 91 is welded and fixed with the biochemical reaction main body 1, a top cover 92 is arranged at the upper end of the reaction shell 91, the rear end of the top cover 92 is connected with the reaction shell 91 in a turnover way through the hinge 99, the reaction cavity 93 is arranged in the reaction shell 91, the heating plate 94 is connected to the left side of the reaction cavity 93 in an inserting way to facilitate the adjustment of the internal temperature, the second control panel 95 is connected to the middle part of the left end of the reaction shell 91 through a bolt, the second power line 96 is arranged in the second control panel 95, the discharging mechanism 97 is arranged at the lower end of the right side of the reaction cavity 93 to facilitate the reasonable adjustment of the number of the placed bacterial colonies, the discharging, hinge 99 is rotatably coupled to the upper end of the rear side of reaction housing 91, and hinge 99 is provided to facilitate opening of top cover 92, and heating plate 94 is electrically connected to second control panel 95.

Wherein discharge mechanism 97 comprises twist grip 971, sealing washer 972, gland 973 and apopore 974, twist grip 971 left end and gland 973 welded fastening, sealing washer 972 encircles in gland 973 right-hand member surface, the gland 973 right-hand member runs through reaction shell 91 lower extreme right side to gland 973 left end carries out plug-in connection with reaction inner chamber 93 left end downside, apopore 974 equidistance is seted up in gland 973 surface.

The left side and the right side of the lower end of the top cover 92 are provided with small convex blocks, and the small convex blocks of the top cover 92 are in plug-in connection with the grooves formed in the left side and the right side of the upper end of the reaction shell 91, so that the sealing performance is better, and water leakage is prevented.

Wherein, the heating plate 94 can heat more than 0 degree to 65 degrees, and the whole heating plate 94 is cuboid, so that the requirements of different strains can be met, and the use efficiency is high.

Wherein, reaction inner chamber 93 sets up to the integral type to reaction inner chamber 93 bottom is provided with the waterproof layer, prevents that the inside seepage from appearing of reaction inner chamber 93.

Wherein, two hinges 99 are symmetrically arranged, and the hinge 99 can rotate 180 degrees, and the rotation angle is large and more convenient.

Wherein, the number of the water outlet holes 974 is seven, and the overall diameter of the water outlet holes 974 is 2CM, and the number is large, so that the circulation amount is increased.

Wherein, the surface of the rotating handle 971 is provided with an anti-slip sleeve, and the handle part of the rotating handle 971 is designed to be in a shape fitting the hand of a user, so that the overall use effect of the user is improved.

The model number of the direct current motor 3 is S86B L130-430.

Wherein, sealing washer 972 adopts the fluorine plain rubber material to make.

This patent direct current motor 3: the direct current electric energy conversion device is a rotating motor which can convert direct current electric energy into mechanical energy or convert mechanical energy into direct current electric energy, can realize the mutual conversion of the direct current electric energy and the mechanical energy, and is a direct current motor when the direct current electric energy conversion device is used as a motor to convert electric energy into mechanical energy; when the generator operates, the generator is a direct current generator and converts mechanical energy into electric energy; the hinge 99: also known as hinges, which are mechanical devices used to connect two solid bodies and allow relative rotation between them, can be made of movable components or of foldable materials, the hinges being mainly mounted on doors and windows, while the hinges are more mounted on cabinets.

The working principle is as follows: firstly, a user electrically connects a first control panel 6, then the user can pour organic waste to be fermented into the biochemical reaction main body from a feeding hole 2, after pouring, the user can operate a stirring rod 8 which is rotatably connected with the lower end of a direct current motor 3 through the feeding hole 2 to drive the stirring rod 8 to start to rotate and stir, so that the organic waste is fully contacted with fermentation strains originally placed in the biochemical reaction main body 1, the organic waste can be fully fermented, after the fermentation is finished, the user can pull out a sealing plate 4 to expose an outlet which is formed at the lower end in the biochemical reaction main body 1, then the organic waste after the fermentation is finished can fall into a storage tank 5 from the outlet, then the user can pull out the storage tank 5 to collect the organic waste, but when the conventional biochemical reaction device is used for fermentation, the fermentation strains are usually directly placed into the biochemical reaction main body 1, the fermentation strain is allowed to ferment itself, thereby causing the fermentation time of the strain to be long and affecting the fermentation efficiency of organic waste, therefore, the biochemical reaction device is provided with the pre-reaction device 9 on the outer surface of the upper end of the left side of the biochemical reaction main body 1 to perform the pre-fermentation of the fermentation strain, the fermentation speed is improved, firstly, a user electrically connects the second control panel 95 of the pre-reaction device 9, then opens the top cover 92 on the upper end of the second control panel 95 to expose the reaction inner cavity 93 arranged inside, then, the user can add the strain to be fermented and water into the reaction inner cavity 93, after the addition is completed, the top cover 92 is covered, the reaction inner cavity 93 connected with the inner part of the reaction inner cavity 93 in an inserting way is operated by the second control panel 95 which is electrically connected, the adjustment of the proper temperature of the fermentation strain is performed by the knob arranged on, the user can place the organic waste into the biochemical reaction main body 1, in the time period, the fermentation strain in the reaction inner cavity 93 starts to ferment rapidly, under the matching of the ventilation opening arranged at the upper end of the top cover 92, the temperature and oxygen required by the fermentation strain are supplied, after the fermentation is completed, the user can open the originally closed discharge port 98 by rotating the rotary handle 971 of the discharge mechanism 97, then the fermentation strain in the reaction cavity 93 can flow into the discharge hole 98 through the water outlet hole 974 formed on the outer surface of the sealing pipe 973, and the organic waste flows into the biochemical reaction main body 1 along with the discharge port 98, and is fully contacted with the organic waste which is put in advance, so that the fermentation of the organic waste is realized, and the arrangement of the pre-reaction device 9 achieves the effects of pre-fermenting the fermentation strains, improving the fermentation speed of the fermentation strains and improving the fermentation speed of the whole biochemical reaction device.

The basic principle and the main characteristics of the utility model and the advantages of the utility model have been shown and described above, and the utility model discloses the standard part that uses all can purchase from the market, and dysmorphism piece all can be customized according to the record of the description with the drawing, and the concrete connection mode of each part all adopts conventional means such as ripe bolt rivet among the prior art, welding, and machinery, part and equipment all adopt prior art, conventional model, and conventional connection mode in the prior art is adopted in addition to circuit connection, and the details are not repeated here.

It is obvious to a person skilled in the art that the invention is not restricted to details of the above-described exemplary embodiments, but that it can be implemented in other specific forms without departing from the spirit or essential characteristics of the invention. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Furthermore, it should be understood that although the present description refers to embodiments, not every embodiment may contain only a single embodiment, and such description is for clarity only, and those skilled in the art should integrate the description, and the embodiments may be combined as appropriate to form other embodiments understood by those skilled in the art.

Claims (8)

1. A biochemical reaction device comprises a biochemical reaction main body (1), a feed inlet (2), a direct current motor (3), a sealing plate (4) and a storage tank (5), a feed inlet (2) is arranged on the right side of the top end of the biochemical reaction main body (1), a direct current motor (3) is arranged in the middle of the top end of the biochemical reaction main body (1), the lower end of the direct current motor (3) is rotationally connected with a stirring rod (8), the rear end of the sealing plate (4) is connected with the biochemical reaction main body (1) in an inserting way, the sealing plate (4) and the lower storage tank (5) are symmetrically arranged, the rear end of the storage tank (5) is connected with the biochemical reaction main body (1) in an inserting way, a first control panel (6) is arranged at the lower end of the left side of the front end of the biochemical reaction main body (1), a first power line (7) is arranged in the first control panel (6), the direct current motor (3) is electrically connected with the first control panel (6);

the method is characterized in that: still include reaction unit (9) in advance, reaction unit (9) is installed in biochemical reaction main part (1) left side upper end surface in advance, reaction unit (9) comprises reaction shell (91), top cap (92), reaction inner chamber (93), hot plate (94), second control panel (95), second power cord (96), discharge mechanism (97), discharge gate (98) and hinge (99) in advance, reaction shell (91) right-hand member and biochemical reaction main part (1) welded fastening, top cap (92) set up in reaction shell (91) upper end to top cap (92) rear end carries out the upset through hinge (99) and reaction shell (91) and is connected, reaction inner chamber (93) are seted up inside reaction shell (91), hot plate (94) plug-in connection is in reaction inner chamber (93) left side, second control panel (95) pass through bolted connection in reaction shell (91) left end middle part, second power cord (96) set up inside second control panel (95), discharge mechanism (97) set up in reaction inner chamber (93) right side lower extreme, reaction inner chamber (93) right side lower extreme is seted up in discharge gate (98) to discharge gate (98) right-hand member extends and runs through biochemical reaction main part (1) left side upper end, hinge (99) rotate to be connected in reaction shell (91) rear side upper end, hot plate (94) are connected with second control panel (95) electricity.

2. The biochemical reaction device according to claim 1, wherein: discharge mechanism (97) comprises twist grip (971), sealing washer (972), gland (973) and apopore (974), twist grip (971) left end and gland (973) welded fastening, sealing washer (972) encircles in gland (973) right-hand member surface, gland (973) right-hand member runs through reaction shell (91) lower extreme right side to gland (973) left end carries out the plug-in connection with reaction inner chamber (93) left end downside, apopore (974) equidistance is seted up in gland (973) surface.

3. The biochemical reaction device according to claim 1, wherein: the left side and the right side of the lower end of the top cover (92) are provided with small lugs, and the small lugs of the top cover (92) are in plug-in connection with grooves formed in the left side and the right side of the upper end of the reaction shell (91).

4. The biochemical reaction device according to claim 1, wherein: the heating plate (94) can heat at an angle of 0 DEG to 65 DEG or more, and the entire heating plate (94) has a rectangular parallelepiped shape.

5. The biochemical reaction device according to claim 1, wherein: the reaction inner cavity (93) is arranged to be integrated, and a waterproof layer is arranged at the bottom end of the reaction inner cavity (93).

6. The biochemical reaction device according to claim 1, wherein: the two hinges (99) are symmetrically arranged, and the hinges (99) can rotate for 180 degrees.

7. The biochemical reaction device according to claim 2, wherein: seven water outlet holes (974) are formed, and the overall diameter of each water outlet hole (974) is 2 CM.

8. The biochemical reaction device according to claim 2, wherein: the outer surface of the rotating handle (971) is provided with an anti-skidding sleeve, and the handle of the rotating handle (971) is designed to be in a shape fitting the hand of a user.

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