CN217677556U - Novel feed production intelligent control device based on microorganism - Google Patents

Abstract

The utility model discloses a novel feed production intelligent control device based on microorganism, include warm water storage mechanism, expand and bank up mechanism, temporary storage mechanism, the buffer gear of weighing, feed proportioning mechanism, packaging mechanism and electric cabinet with expanding and bank up and connect through first pipe connection between the mechanism, expand and bank up and connect through the second pipe connection between mechanism and the temporary storage mechanism, the buffer gear of weighing passes through fourth pipeline and third pipe connection respectively with warm water storage mechanism and temporary storage mechanism, the buffer gear's of weighing output fixedly connected with fifth pipeline, the stainless steel ribbon mixes the machine is installed to one side of fifth pipeline, top one side that the stainless steel ribbon mixed the machine is connected with the seventh pipeline, the seventh pipeline is keeping away from the one end fixedly connected with sixth pipeline that the stainless steel ribbon mixed the machine. The utility model discloses a design realizes intelligent control to microbial feed production, makes each item standard of microbial feed realize relatively accurate control.

Description

Novel feed production intelligent control device based on microorganism

Technical Field

The utility model relates to a novel feed production field of microorganism especially relates to a based on novel feed production intelligent control device of microorganism.

Background

The microbial feed takes microbes and complex enzyme as biological feed starter strains, and raw materials of the feed are converted into microbial mycoprotein, bioactive small peptide amino acid, microbial active probiotics and a complex enzyme preparation which are integrated into a biological fermentation feed.

The existing microbial feed is manually fermented, so that time and labor are wasted, the feed fermentation effect is extremely poor, various standards of the fermented feed cannot be accurately controlled, and animals are difficult to digest after eating the feed.

Therefore, it is desirable to provide a novel intelligent control device for feed production based on microorganisms to solve the above problems.

SUMMERY OF THE UTILITY MODEL

The utility model aims to solve the technical problem that the fermentation is all gone through the manual work to current microbial feed, has also leaded to the fermented effect of fodder extremely poor when wasting time and energy, to the unable accurate control of each item standard of fermented fodder, makes the animal be difficult to digest after eating the fodder.

In order to solve the technical problem, the utility model discloses a technical scheme be: the novel feed production intelligent control device based on the microorganisms comprises a warm water storage mechanism, an expanding culture mechanism, a temporary storage mechanism, a weighing buffer mechanism, a batching mechanism, a packing mechanism and an electric cabinet;

the warm water storage mechanism and the expanding culture mechanism are connected through a first pipeline, the expanding culture mechanism and the temporary storage mechanism are connected through a second pipeline, and the weighing buffer mechanism, the warm water storage mechanism and the temporary storage mechanism are respectively connected through a fourth pipeline and a third pipeline;

weighing buffer gear's output fixedly connected with fifth pipeline, the stainless steel spiral shell area is installed in one side of keeping away from weighing buffer gear and is mixed the machine, top one side that the stainless steel spiral shell area was mixed the machine is connected with the seventh pipeline, the seventh pipeline is keeping away from the one end fixedly connected with sixth pipeline that the stainless steel spiral shell area was mixed the machine, screw conveyer has been placed to one side bottom that the stainless steel spiral shell area was mixed the machine, the finished product tray has been placed to one side of baling mechanism, install the display screen on the electric cabinet.

The utility model discloses further set up to: warm water storage mechanism includes first water supply line, install first manual stop valve and first pneumatic valve on the first water supply line respectively, the bottom of first water supply line output is provided with Wen Shuiguan, install the floater level gauge on the warm water jar, heating rod and temperature sensor are installed respectively to Wen Shuiguan's inner wall, the bottom fixedly connected with warm water output pipeline of warm water jar, first warm water manual stop valve and first warm water pneumatic valve and second warm water manual stop valve and second warm water pneumatic valve are installed respectively to fourth pipeline and first pipeline in the one end that is close to warm water output pipeline.

Through above-mentioned technical scheme, heat the water in the warm water jar through the heating rod, water level and temperature in the warm water jar can be monitored respectively to floater level gauge and temperature sensor, through the manual stop valve of installation on fourth pipeline and the first pipeline and pneumatic valve control warm water in the warm water jar respectively the transport of weighing buffer gear and expanding culture mechanism.

The utility model further sets up to: expand and cultivate mechanism including the air compressor machine, the output fixedly connected with air output pipeline of air compressor machine, the gas holder is installed to air output pipeline's output, the delivery outlet fixedly connected with high-pressure air pipeline of gas holder, the manual stop valve of air is installed to high-pressure air pipeline's outer wall, pressure reduction filter is installed to high-pressure air pipeline's output, gas transmission pipeline is installed to pressure reduction filter's output, gas transmission pipeline is provided with to expand in the one end of keeping away from pressure reduction filter and cultivates the jar body, expand to cultivate the top of cultivateing the jar body and install second water supply line and pH value sensor respectively, expand to cultivate the bottom of cultivateing the jar body and install respectively to expand to cultivate a jar drain, expand to cultivate a jar manual stop valve and expand to cultivate a jar start-up valve with earth.

Through above-mentioned technical scheme, become high-pressure air through the air compressor machine with the air in the gas holder, export to the bottom of expanding and banking up the jar body by gas transmission pipeline, PH value sensor can expand and banked up jar internal portion's PH value real-time detection with earth.

The utility model further sets up to: and a water suction pump is installed at one end of the second pipeline.

Through the technical scheme, the bacterial liquid in the expanding culture tank body is pumped to the temporary storage mechanism through the water suction pump.

The utility model discloses further set up to: temporary storage mechanism is including the jar body of keeping in, jar drain, the manual stop valve of jar and the jar pneumatic valve of keeping in are installed respectively to the bottom of the jar body of keeping in.

Through above-mentioned technical scheme, buffer gear weighs can be transmitted to through the third pipeline with the fungus liquid of keeping in to temporary storage mechanism.

The utility model discloses further set up to: the buffer gear of weighing is including the buffer tank of weighing, buffer tank pneumatic valve is installed to the bottom of buffer tank of weighing, the output fixedly connected with fungus liquid output pipeline of buffer tank pneumatic valve, fungus liquid output water pump is installed in the one end of keeping away from buffer tank pneumatic valve to fungus liquid output pipeline.

Through above-mentioned technical scheme, add fungus liquid and water in the buffer gear of weighing, the fungus liquid temperature sensor and the weighing sensor of the buffer tank outer wall installation of weighing can be to the temperature and the weight real-time detection of its inside fungus liquid.

The utility model discloses further set up to: the batching mechanism is including throwing material steel bars and high-pressure drum awl end pulse dust remover, fodder transport pipe way is installed to the bottom of high-pressure drum awl end pulse dust remover, the output bottom of fodder transport pipe way is provided with the storage tank, the bottom of storage tank is provided with the batching jar, stainless steel buffering fill has been placed to the bottom of batching jar, transmission device has been placed to the bottom of stainless steel buffering fill.

Through above-mentioned technical scheme, the staff pours the fodder into, and high-pressure cylinder awl end pulse dust remover can get rid of the tiny granule that the fodder produced, gets into the storage tank through fodder transportation pipeline, through the allotment of different proportions, finally by transmission device transmission in the batching jar.

The utility model discloses further set up to: the packaging mechanism comprises an electronic scale and a package sewing conveyor, wherein the hot melting sealing machine is installed on one side, close to the electronic scale, of the package sewing conveyor.

Through above-mentioned technical scheme, place the wrapping bag below screw conveyer's the discharge gate, the electronic scale can carry out the ration to the fodder of output, seals the wrapping bag through the hot melt capper, transmits through seam package conveyer at last, accomplishes the packing.

The utility model discloses further set up to: the electric control box is electrically connected with each mechanism through a wire.

Through the technical scheme, the data in each mechanism are transmitted and analyzed through the display screen arranged on the electric cabinet, and corresponding change and corresponding control are performed according to the required values.

The beneficial effects of the utility model are as follows:

1. the utility model realizes intelligent control on the production of microbial feed, and realizes accurate control on various data of feed by matching a plurality of mechanisms, and increasing the detection on the temperature, pH value, water temperature and the like of microbial fermentation in the mechanisms, so that the feed can be fully fermented and is easier for animals to digest and absorb;

2. the utility model transmits and analyzes the data between the mechanisms displayed on the display screen of the electric cabinet, and correspondingly changes and controls according to the required value, thereby ensuring the product quality and greatly improving the production efficiency;

3. the utility model discloses a only need operate each position of device through the few number, monitor between each mechanism through the electric cabinet, saved the manpower greatly.

Drawings

FIG. 1 is a view showing the structure of the apparatus of the present invention;

FIG. 2 is a structural diagram of a warm water storage mechanism of the present invention;

FIG. 3 is a structural diagram of the expanding culture mechanism of the present invention;

FIG. 4 is a structural diagram of the temporary storage mechanism of the present invention;

FIG. 5 is a structural view of the weighing buffer mechanism of the present invention;

FIG. 6 is a structural diagram of the batching mechanism of the present invention;

fig. 7 is a structural diagram of the packing mechanism of the present invention.

In the figure: 1. a warm water storage mechanism; 101. a first tap water pipe; 102. a first manual stop valve; 103. a first pneumatic valve; 104. wen Shuiguan; 105. a floating ball liquid level meter; 106. a heating rod; 107. a temperature sensor; 108. a warm water output pipeline; 109. a first warm water manual stop valve; 110. a first warm water pneumatic valve; 111. a second warm water manual stop valve; 112. a second warm water pneumatic valve; 2. a first conduit; 3. an expanding culture mechanism; 301. an air compressor; 302. an air output duct; 303. a gas storage tank; 304. a high pressure air conduit; 305. an air manual stop valve; 306. a pressure reducing filter; 307. a gas pipeline; 308. expanding the culture tank body; 309. a second tap water pipe; 310. a pH sensor; 311. a blow-off port of the expanding culture tank; 312. a manual stop valve of the expanding culture tank; 313. starting a valve of the expanding culture tank; 4. a second conduit; 5. a temporary storage mechanism; 501. temporarily storing the tank body; 502. a drain outlet of the temporary storage tank; 503. a temporary storage tank manual stop valve; 504. a temporary storage tank pneumatic valve; 6. a third pipeline; 7. a fourth conduit; 8. a weighing buffer mechanism; 801. a weighing buffer tank; 802. a buffer tank pneumatic valve; 803. a bacteria liquid output pipeline; 804. a bacteria liquid output water pump; 9. a fifth pipeline; 10. a batching mechanism; 1001. feeding a steel grid; 1002. a high-pressure cylindrical conical bottom pulse dust collector; 1003. a feed transport pipeline; 1004. a material storage tank; 1005. a dosing tank; 1006. a stainless steel buffer hopper; 1007. a transmission device; 11. a sixth pipeline; 12. a seventh pipe; 13. a stainless steel ribbon mixer; 14. a screw conveyor; 15. a packaging mechanism; 1501. an electronic scale; 1502. a hot-melting sealing machine; 1503. a bag sewing conveyor; 16. a finished product tray; 17. an electric cabinet; 18. and a display screen.

Detailed Description

The following detailed description of the preferred embodiments of the present invention will be provided in conjunction with the accompanying drawings, so as to enable those skilled in the art to more easily understand the advantages and features of the present invention, and thereby define the scope of the invention more clearly and clearly.

Referring to fig. 1, an intelligent control device for novel feed production based on microorganisms comprises a warm water storage mechanism 1, a culture expanding mechanism 3, a temporary storage mechanism 5, a weighing buffer mechanism 8, a batching mechanism 10, a packing mechanism 15 and an electric cabinet 17;

as shown in fig. 1 and 2, the warm water storage mechanism 1 includes a first tap water pipeline 101, a first manual stop valve 102 and a first pneumatic valve 103 are respectively installed on the first tap water pipeline 101, a Wen Shuiguan is arranged at the bottom of the output end of the first tap water pipeline 101, a floating ball level meter 105 is installed on the warm water tank 104, a heating rod 106 and a temperature sensor 107 are respectively installed on the inner wall of the warm water tank 104, a warm water output pipeline 108 is fixedly connected to the bottom of Wen Shuiguan, a first warm water manual stop valve 109 and a first warm water pneumatic valve 110 and a second warm water pneumatic valve 111 and a second warm water pneumatic valve 112 are respectively installed at one end of the fourth pipeline 7 and the first pipeline 2 close to the warm water output pipeline 108, water in the warm water tank 104 is heated by the heating rod 106, the water level meter 105 and the temperature sensor 107 can respectively monitor the water level and the water temperature in the warm water tank 104, and a water level buffer mechanism 8 and a water expansion and a water weighing mechanism 3 are respectively installed in the manual and the manual pneumatic valve 104;

as shown in fig. 1 and 3, the expanding culture mechanism 3 includes an air compressor 301, an output end of the air compressor 301 is fixedly connected with an air output pipeline 302, an output end of the air output pipeline 302 is provided with an air storage tank 303, an output port of the air storage tank 303 is fixedly connected with a high-pressure air pipeline 304, an outer wall of the high-pressure air pipeline 304 is provided with an air manual stop valve 305, an output end of the high-pressure air pipeline 304 is provided with a pressure reducing filter 306, an output end of the pressure reducing filter 306 is provided with an air transmission pipeline 307, one end of the air transmission pipeline 307 far away from the pressure reducing filter 306 is provided with an expanding culture tank 308, a top of the expanding culture tank 308 is respectively provided with a second tap water pipeline 309 and a PH sensor 310, a bottom of the expanding culture tank 308 is respectively provided with an expanding culture tank discharge outlet 311, an expanding culture tank manual stop valve 312 and an expanding culture tank starting valve 313, air in the air storage tank 303 is changed into high-pressure air by the air compressor 301, the air transmission pipeline 307 is output to the bottom of the expanding culture tank 308, and the PH sensor 310 can detect a PH value in real time inside the expanding culture tank 308;

as shown in fig. 1 and 4, the temporary storage mechanism 5 comprises a temporary storage tank body 501, a temporary storage tank drain outlet 502, a temporary storage tank manual stop valve 503 and a temporary storage tank pneumatic valve 504 are respectively installed at the bottom of the temporary storage tank body 501, and the temporary storage mechanism 5 can transmit the temporarily stored bacterial liquid to the weighing buffer mechanism 8 through a third pipeline 6;

as shown in fig. 1 and 5, the weighing buffer mechanism 8 comprises a weighing buffer tank 801, a buffer tank pneumatic valve 802 is installed at the bottom of the weighing buffer tank 801, a bacterial liquid output pipeline 803 is fixedly connected to the output end of the buffer tank pneumatic valve 802, a bacterial liquid output water pump 804 is installed at one end of the bacterial liquid output pipeline 803, which is far away from the buffer tank pneumatic valve 802, bacterial liquid and water are added into the weighing buffer mechanism 8, and a bacterial liquid temperature sensor and a weighing sensor which are installed on the outer wall of the weighing buffer tank 801 can detect the temperature and the weight of the bacterial liquid inside the weighing buffer tank in real time;

as shown in fig. 1 and fig. 6, the batching mechanism 10 includes a feeding steel grid 1001 and a high-pressure cylinder conical bottom pulse dust collector 1002, a feed conveying pipeline 1003 is installed at the bottom of the high-pressure cylinder conical bottom pulse dust collector 1002, a storage tank 1004 is arranged at the bottom of an output end of the feed conveying pipeline 1003, a batching tank 1005 is arranged at the bottom of the storage tank 1004, a stainless steel buffer hopper 1006 is placed at the bottom of the batching tank 1005, a transmission device 1007 is placed at the bottom of the stainless steel buffer hopper 1006, a worker pours the feed into the batching mechanism, the high-pressure cylinder conical bottom pulse dust collector 1002 can remove fine particles generated by the feed, the fine particles enter the storage tank 1004 through the feed conveying pipeline 1003, are batched in different proportions in the batching tank 1005, and are finally transmitted by the transmission device 1007;

as shown in fig. 1 and 7, the packaging mechanism 15 includes an electronic scale 1501 and a bag sewing conveyor 1503, the bag sewing conveyor 1503 is provided with a hot-melt sealing machine 1502 at one side close to the electronic scale 1501, the packaging bag is placed under the discharge port of the screw conveyor 14, the electronic scale 1501 can quantify the output feed, the packaging bag is sealed by the hot-melt sealing machine 1502, and finally the output feed is conveyed by the bag sewing conveyor 1503 to complete the packaging;

as shown in fig. 1, the electric cabinet 17 is electrically connected to each mechanism through a wire, data in each mechanism is transmitted and analyzed through a display screen 18 installed on the electric cabinet 17, and corresponding change and corresponding control are performed according to a required value;

the warm water storage mechanism 1 is connected with the culture expanding mechanism 3 through a first pipeline 2, the culture expanding mechanism 3 is connected with the temporary storage mechanism 5 through a second pipeline 4, a water suction pump is mounted at one end of the second pipeline 4, bacterial liquid in the culture expanding tank body 308 is pumped into the temporary storage mechanism 5 through the water suction pump, and the weighing buffer mechanism 8 is connected with the warm water storage mechanism 1 and the temporary storage mechanism 5 through a fourth pipeline 7 and a third pipeline 6 respectively;

as shown in fig. 1, the output end of the weighing buffer mechanism 8 is fixedly connected with a fifth pipeline 9, the fifth pipeline 9 is provided with a stainless steel ribbon mixer 13 at one side far away from the weighing buffer mechanism 8, one side of the top of the stainless steel ribbon mixer 13 is connected with a seventh pipeline 12, the seventh pipeline 12 is provided with a sixth pipeline 11 at one end far away from the stainless steel ribbon mixer 13, the sixth pipeline 11 is provided with a batching mechanism 10 at one end far away from the seventh pipeline 12, a spiral conveyor 14 is placed at the bottom of one side of the stainless steel ribbon mixer 13, a packing mechanism 15 is arranged at the bottom of one side of the spiral conveyor 14, a finished product tray 16 is placed at one side of the packing mechanism 15, and a display screen 18 is installed on an electric cabinet 17.

The utility model discloses when using, construct 1 to expanding and cultivate mechanism 3 and 8 output warm water of buffer gear of weighing through warm water storage mechanism, the microorganism is expanding and cultivates jar body 308 and ferment, come to carry out real time monitoring to the pH value in the microorganism fermentation through pH value sensor 310, become high-pressure gas through air compressor 301 with the gas in the gas holder 303, carry and expand the bottom of cultivateing jar body 308, after the fermentation, export the fungus liquid through second pipeline 4 in temporary storage mechanism 5, rethread third pipeline 6 exports the fungus liquid to buffer gear 8 of weighing, the staff can transport the feed storage tank 1004 through feed transport pipeline 1003 simultaneously, allocate the feed, carry stainless steel ribbon mixer 13 at last, the fungus liquid also can add stainless steel ribbon mixer 13 through fifth pipeline 9 simultaneously, export final packing mechanism 15 after mixing, in device working process, come to detect and analyze the data between each mechanism through electric cabinet 17 and display screen 18.

The above only is the embodiment of the present invention, not limiting the patent scope of the present invention, all the equivalent structures or equivalent processes that are used in the specification and the attached drawings or directly or indirectly applied to other related technical fields are included in the patent protection scope of the present invention.

Claims (9)

1. The utility model provides a novel feed production intelligent control device based on microorganism which characterized in that: comprises a warm water storage mechanism (1), an expanding culture mechanism (3), a temporary storage mechanism (5), a weighing buffer mechanism (8), a batching mechanism (10), a packing mechanism (15) and an electric cabinet (17);

the warm water storage mechanism (1) is connected with the expanding culture mechanism (3) through a first pipeline (2), the expanding culture mechanism (3) is connected with the temporary storage mechanism (5) through a second pipeline (4), and the weighing buffer mechanism (8) is connected with the warm water storage mechanism (1) and the temporary storage mechanism (5) through a fourth pipeline (7) and a third pipeline (6) respectively;

weighing buffer gear (8) output fixedly connected with fifth pipeline (9), the stainless steel ribbon mixing machine (13) is installed in one side of keeping away from weighing buffer gear (8) in fifth pipeline (9), top one side that the stainless steel ribbon mixing machine (13) is connected with seventh pipeline (12), seventh pipeline (12) is in one end fixedly connected with sixth pipeline (11) of keeping away from the stainless steel ribbon mixing machine (13), screw conveyer (14) have been placed to one side bottom that the stainless steel ribbon mixing machine (13), finished product tray (16) have been placed to one side of baling mechanism (15), install display screen (18) on electric cabinet (17).

2. The intelligent control device for the novel feed production based on microorganisms, according to claim 1, is characterized in that: the warm water storage mechanism (1) comprises a first tap water pipeline (101), a first manual stop valve (102) and a first pneumatic valve (103) are installed on the first tap water pipeline (101) respectively, the bottom of an output end of the first tap water pipeline (101) is provided with Wen Shuiguan (104), a floating ball liquid level meter (105) is installed on Wen Shuiguan (104), a heating rod (106) and a temperature sensor (107) are installed on the inner wall of Wen Shuiguan (104) respectively, the bottom of Wen Shuiguan (104) is fixedly connected with a warm water output pipeline (108), and a first warm water manual stop valve (109) and a first warm water pneumatic valve (110) and a second warm water manual stop valve (111) and a second warm water pneumatic valve (112) are installed at one end close to the warm water output pipeline (108) of a fourth pipeline (7) and a first pipeline (2) respectively.

3. The intelligent control device for the novel feed production based on microorganisms, according to claim 1, is characterized in that: the expanding culture mechanism (3) comprises an air compressor (301), an air output pipeline (302) is fixedly connected with the output end of the air compressor (301), an air storage tank (303) is installed at the output end of the air output pipeline (302), a high-pressure air pipeline (304) is fixedly connected with the output end of the air storage tank (303), an air manual stop valve (305) is installed on the outer wall of the high-pressure air pipeline (304), a decompression filter (306) is installed at the output end of the high-pressure air pipeline (304), gas transmission pipeline (307) are installed to the output of decompression filter (306), gas transmission pipeline (307) are provided with the expanding culture jar body (308) in the one end of keeping away from decompression filter (306), second water supply pipeline (309) and pH value sensor (310) are installed respectively to the top of the expanding culture jar body (308), expanding culture jar drain (311), expanding culture jar manual stop valve (312) and expanding culture jar starting valve (313) are installed respectively to the bottom of the expanding culture jar body (308).

4. The intelligent control device for the novel feed production based on microorganisms, according to claim 1, is characterized in that: and a water suction pump is installed at one end of the second pipeline (4).

5. The intelligent control device for the novel feed production based on microorganisms, according to claim 1, is characterized in that: temporary storage mechanism (5) are including the jar body of temporary storage (501), temporary storage jar drain (502), the manual stop valve of the jar of temporary storage (503) and the jar pneumatic valve of temporary storage (504) are installed respectively to the bottom of the jar body of temporary storage (501).

6. The intelligent control device for the novel feed production based on microorganisms, according to claim 1, is characterized in that: buffer gear (8) of weighing are including the buffer tank (801) of weighing, buffer tank pneumatic valve (802) are installed to the bottom of buffer tank (801) of weighing, the output fixedly connected with fungus liquid output pipe (803) of buffer tank pneumatic valve (802), fungus liquid output water pump (804) are installed in the one end of keeping away from buffer tank pneumatic valve (802) in fungus liquid output pipe (803).

7. The intelligent control device for the novel feed production based on microorganisms, according to claim 1, is characterized in that: batching mechanism (10) are including throwing material steel bars (1001) and high-pressure cylinder awl end pulse dust remover (1002), fodder transportation pipeline (1003) are installed to the bottom of high-pressure cylinder awl end pulse dust remover (1002), the output bottom of fodder transportation pipeline (1003) is provided with storage tank (1004), the bottom of storage tank (1004) is provided with batching jar (1005), stainless steel buffering fill (1006) have been placed to the bottom of batching jar (1005), transmission device (1007) have been placed to the bottom of stainless steel buffering fill (1006).

8. The intelligent control device for the novel feed production based on microorganisms, according to claim 1, is characterized in that: the packaging mechanism (15) comprises an electronic scale (1501) and a bag sewing conveyor (1503), wherein the bag sewing conveyor (1503) is provided with a hot melting sealing machine (1502) at one side close to the electronic scale (1501).

9. The intelligent control device for the novel feed production based on microorganisms, according to claim 1, is characterized in that: the electric control box (17) is electrically connected with each mechanism through a lead.

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