CN216898173U - High-efficient cooling device of fermented feed raw material - Google Patents

Abstract

The utility model relates to the field of cooling equipment, in particular to a high-efficiency cooling device for fermented feed raw material materials. Feed ingredient fermentation powder material high-efficient cooling device includes the drying cabinet, first drop feed mechanism, the second drop feed mechanism, water-cooling mechanism, air-cooled mechanism and tiling mechanism, a first drop feed mechanism for placing the material is installed on the one end inner wall of drying cabinet, a second drop feed mechanism for receiving the material that falls from first drop feed mechanism installs on the other end inner wall of drying cabinet, a water-cooling mechanism for cooling down to first drop feed mechanism and second drop feed mechanism is installed in the backup pad, a tiling mechanism for carrying out the material on first drop feed mechanism and the second drop feed mechanism evenly stirs is installed on the both sides inner wall of drying cabinet. The efficient cooling device for the feed raw material fermentation powder material provided by the utility model has the advantages that the dried microbial degradation material and the feed raw material can be rapidly cooled, and the material is prevented from caking due to overhigh temperature.

Description

High-efficient cooling device of fermented feed raw materials material

Technical Field

The utility model relates to the field of cooling equipment, in particular to a high-efficiency cooling device for fermented feed raw material materials.

Background

In the process of fermenting the microbial fermented feed, macromolecules in feed raw materials are decomposed into micromolecular peptides, carbohydrates of the macromolecules are degraded into disaccharide, trisaccharide and the like, and meanwhile, a large amount of metabolites such as enzymes, organic acids and the like are generated in the growth process of the microbes.

The mixture of the microbial degradation substances and the feed raw materials is not sufficiently cooled after being dried, so that the caking phenomenon of finished products is easily caused, and the caking degree is more serious along with the extension of the stacking time.

Therefore, there is a need to provide a new device for efficiently cooling fermented powder materials of feedstuff to solve the above technical problems.

SUMMERY OF THE UTILITY MODEL

In order to solve the technical problems, the utility model provides the efficient cooling device for the feed raw material fermentation powder material, which can rapidly cool the dried microbial degradation material and the feed raw material and prevent the material from caking due to overhigh temperature.

The utility model provides a feed raw material fermentation powder material efficient cooling device, which comprises: the drying box is characterized in that a supporting plate is fixedly arranged on the side wall of the drying box, and a supporting frame is fixedly arranged at the bottom of the supporting plate;

the first discharging mechanism for placing materials is arranged on the inner wall of one end of the drying box;

the second discharging mechanism is used for receiving the materials falling from the first discharging mechanism and is arranged on the inner wall of the other end of the drying box;

the water cooling mechanism is used for cooling the first discharging mechanism and the second discharging mechanism and is arranged on the supporting plate;

the air cooling mechanism is used for cooling the inside of the drying box and is also arranged on the supporting plate;

and the tiling mechanism is used for uniformly turning the materials on the first discharging mechanism and the second discharging mechanism and is arranged on the inner walls of the two sides of the drying box.

Preferably, first drop feed mechanism includes first motor and first water-cooling baffle, first motor fixed mounting is on the outer wall of drying cabinet, one end of first water-cooling baffle rotates with one side inner wall of drying cabinet to be connected, the other end of first water-cooling baffle and the output fixed connection of first motor.

Preferably, the second drop feed mechanism comprises a second motor and a second water-cooling partition plate, the second motor is fixedly installed on the outer wall of the drying box, two ends of the second water-cooling partition plate are rotatably connected with the inner wall of one side of the drying box, and the other end of the second water-cooling partition plate is fixedly connected with the output end of the second motor.

Preferably, the first discharging mechanism and the second discharging mechanism are respectively provided with a plurality of groups, and the first discharging mechanism and the second discharging mechanism are distributed on the inner walls of the two sides of the drying box in a staggered mode.

Preferably, the water-cooling mechanism includes refrigerating unit, connecting pipe, first inlet tube and second inlet tube, refrigerating unit fixed mounting is at the top of backup pad, the connecting pipe is connected with refrigerating unit's the end of intaking, the second advances water piping connection at refrigerating unit's a set of water outlet end and each group between the first water-cooling baffle, the second advances water piping connection another group of water outlet end and each group at refrigerating unit between the second water-cooling baffle.

Preferably, tiling mechanism includes third motor, lead screw and push pedal, all be equipped with multiunit third motor on the drying cabinet both ends outer wall, the output fixed mounting that the output of third motor is located the inside drying cabinet has the lead screw, a plurality of groups the top of first water-cooling baffle and second water-cooling baffle is arranged respectively in to the lead screw, threaded connection has the push pedal on the pole wall of lead screw, just the push pedal still with the inside wall sliding connection of drying cabinet.

Preferably, the air cooling mechanism comprises a fan, an air inlet pipe and an air outlet pipe, the fan is connected with an air inlet of the refrigerating unit, the air inlet pipe is connected between an air outlet end of the refrigerating unit and the drying box, and the air outlet pipe is installed at the top of the drying box.

Preferably, the feeder hopper is installed at the top of drying cabinet, the top joint of feeder hopper has sealed lid, the discharging pipe is installed to the bottom of drying cabinet, the externally mounted of discharging pipe has the valve.

Compared with the related art, the efficient cooling device for the feed raw material fermentation powder material provided by the utility model has the following beneficial effects:

the utility model provides a feed raw material fermentation powder material efficient cooling device, which comprises the steps of firstly pouring dried microbial degradation substances and feed raw materials into a drying box, enabling the materials to fall onto a group of first discharging mechanisms, then uniformly stirring the materials through a tiling mechanism, carrying out cooling treatment through a water cooling mechanism, enabling the first discharging mechanisms to downwards stir after a period of time to enable the materials to fall onto a group of second discharging mechanisms, uniformly stirring and tiling through the tiling mechanism again, enabling the water cooling mechanism to cool again, then sprinkling the materials onto another group of first discharging mechanisms, and sequentially circulating for multiple times of cooling, so that the materials can be thoroughly cooled, and the falling materials can be air-cooled through an air cooling mechanism when falling, further cooling the materials, and preventing the materials from being agglomerated due to overhigh temperature.

Drawings

FIG. 1 is a schematic structural diagram of an embodiment of the apparatus for efficiently cooling fermented powdered materials of raw materials for feed provided by the present invention;

FIG. 2 is a schematic view of the internal structure of a drying box of the efficient cooling device for fermented powdered materials of feedstuff shown in FIG. 1;

FIG. 3 is a front view of the inside of a drying cabinet of the apparatus for efficiently cooling fermented powdered material of feedstuff shown in FIG. 1.

Reference numbers in the figures: 1. a drying oven; 11. a support plate; 12. a discharge pipe; 2. a first discharging mechanism; 21. a first motor; 22. a first water-cooled partition; 3. a second discharging mechanism; 31. a second motor; 32. a second water-cooled partition; 4. a water cooling mechanism; 41. a refrigeration unit; 42. a connecting pipe; 43. a first water inlet pipe; 44. a second water inlet pipe; 5. an air cooling mechanism; 51. a fan; 52. an air inlet pipe; 53. an air outlet pipe; 6. a flat laying mechanism; 61. a third motor; 62. a screw rod; 63. pushing the plate; 7. a support frame; 8. a feed hopper; 81. and (7) sealing the cover.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the utility model and are not intended to limit the utility model.

Specific implementations of the present invention are described in detail below with reference to specific embodiments.

Referring to fig. 1 to 3, an embodiment of the present invention provides a device for efficiently cooling a fermented powdered material of a feedstuff, including: the drying oven comprises a drying oven 1, a first discharging mechanism 2, a second discharging mechanism 3, a water cooling mechanism 4, an air cooling mechanism 5 and a flattening mechanism 6, wherein a supporting plate 11 is fixedly arranged on the side wall of the drying oven 1, a supporting frame 7 is fixedly arranged at the bottom of the supporting plate 11, a first discharging mechanism 2 for placing materials is arranged on the inner wall of one end of the drying box 1, a second discharging mechanism 3 for receiving the materials falling from the first discharging mechanism 2 is arranged on the inner wall of the other end of the drying box 1, the water cooling mechanism 4 for cooling the first discharging mechanism 2 and the second discharging mechanism 3 is arranged on the supporting plate 11, an air cooling mechanism 5 for cooling the inside of the drying box 1 is also installed on the supporting plate 11, and the tiling mechanisms 6 for uniformly turning the materials on the first discharging mechanism 2 and the second discharging mechanism 3 are arranged on the inner walls of the two sides of the drying box 1.

It should be noted that: firstly, pour into drying cabinet 1 with the microbial degradation material and the feed ingredient of drying, the material can fall on a set of first drop feed mechanism 2 earlier, then can evenly turn the material through tiling mechanism 6, and cool down the processing through water cooling mechanism 4, first drop feed mechanism 2 stirs downwards after a period and lets the material fall on a set of second drop feed mechanism 3, evenly turn the tiling through tiling mechanism 6 once more, let water cooling mechanism 4 cool down once more, later with the material spill on another set of first drop feed mechanism 2, circulate in proper order and cool down many times, can cool down thoroughly the material, and can also carry out the forced air cooling to the material of whereabouts through forced air cooling mechanism 5 when the material whereabouts, further cool off the material, prevent that the material temperature is too high and the caking.

In an embodiment of the present invention, referring to fig. 1 to 3, the first material discharging mechanism 2 includes a first motor 21 and a first water-cooling partition plate 22, the first motor 21 is fixedly installed on an outer wall of the drying box 1, one end of the first water-cooling partition plate 22 is rotatably connected to an inner wall of one side of the drying box 1, and the other end of the first water-cooling partition plate 22 is fixedly connected to an output end of the first motor 21;

the second discharging mechanism 3 comprises a second motor 31 and a second water-cooling partition plate 32, the second motor 31 is fixedly installed on the outer wall of the drying box 1, two ends of the second water-cooling partition plate 32 are rotatably connected with the inner wall of one side of the drying box 1, and the other end of the second water-cooling partition plate 32 is fixedly connected with the output end of the second motor 31;

the first discharging mechanisms 2 and the second discharging mechanisms 3 are respectively provided with a plurality of groups, and the first discharging mechanisms 2 and the second discharging mechanisms 3 of the groups are distributed on the inner walls of the two sides of the drying box 1 in a staggered manner;

the water cooling mechanism 4 comprises a refrigerating unit 41, a connecting pipe 42, a first water inlet pipe 43 and a second water inlet pipe 44, wherein the refrigerating unit 41 is fixedly arranged at the top of the supporting plate 11, the connecting pipe 42 is connected with the water inlet end of the refrigerating unit 41, the second water inlet pipe 44 is connected between one group of water outlet ends of the refrigerating unit 41 and each group of first water-cooling partition plates 22, and the second water inlet pipe 44 is connected between the other group of water outlet ends of the refrigerating unit 41 and each group of second water-cooling partition plates 32;

the flat laying mechanism 6 comprises a third motor 61, a screw rod 62 and a push plate 63, a plurality of groups of third motors 61 are arranged on the outer walls of two ends of the drying box 1, the output end of the third motor 61, which is positioned in the drying box 1, is fixedly provided with the screw rod 62, the plurality of groups of screw rods 62 are respectively arranged above the first water-cooling partition plate 22 and the second water-cooling partition plate 32, the rod wall of the screw rod 62 is in threaded connection with the push plate 63, and the push plate 63 is also in sliding connection with the inner side wall of the drying box 1;

it should be noted that: firstly, dried microbial degradation substances and feed raw materials are poured into a drying box 1, the materials fall onto a group of first water-cooling partition plates 22 firstly, at the moment, a refrigerating unit 41 is started, a water pump is externally connected with a connecting pipe 42, water is pumped into the refrigerating unit 41 to be cooled and then is respectively transmitted into each group of first water-cooling partition plates 22 and second water-cooling partition plates 32 through a first water inlet pipe 43 and a second water inlet pipe 44, the cooled materials are subjected to text cooling through the first water-cooling partition plates 22, a group of third motors 61 can be started to work to drive a group of screw rods 62 to rotate forwards and backwards, as the push plates 63 are not only in threaded connection with the screw rods 62 but also in sliding connection with the inner wall of the drying box 1, the screw rods 62 can drive the push plates 63 to move back and forth when rotating forwards and backwards, the materials on the first water-cooling partition plates 22 are uniformly turned back and forth, and the first water-cooling partition plates 22 are further convenient for thoroughly cooling the materials, then after 30 seconds, the first motor 21 is started to work to drive the first water-cooling partition plate 22 paved with the materials to turn downwards, the materials fall on the group of second water-cooling partition plates 32 on the other side of the drying box 1 to be continuously cooled, the other group of third motor 61 is started to work to drive the push plate 63 to uniformly turn the materials on the second water-cooling partition plates 32 to be conveniently cooled, then the second motor 31 is continuously started to work to drive the second water-cooling partition plates 32 to turn downwards after 30 seconds, the materials fall on the next group of first water-cooling partition plates 22 again to be further cooled, so that the materials can continuously fall on the other group of second water-cooling partition plates 32 from the group of first water-cooling partition plates 22, then fall on the other group of first water-cooling partition plates 22 from the group of second water-cooling partition plates 32, are sequentially cooled, finally fall on the bottommost part of the drying box 1, and can be cooled for multiple times, the material can be cooled, and the agglomeration caused by overhigh temperature of the material can be more thoroughly prevented.

In the embodiment of the present invention, referring to fig. 2, the air cooling mechanism 5 includes a fan 51, an air inlet pipe 52 and an air outlet pipe 53, the fan 51 is connected to an air inlet of the refrigeration unit 41, the air inlet pipe 52 is connected between an air outlet end of the refrigeration unit 41 and the drying box 1, and the air outlet pipe 53 is installed at the top of the drying box 1;

it should be noted that: when the material falls from the first water-cooling partition 22 to the second water-cooling partition 32, or falls from the second water-cooling partition 32 to the first water-cooling partition 22, the fan 51 can be started to work to draw air into the drying cabinet 1 through the refrigerating unit 41 to be cooled, and then the air is blown into the drying cabinet 1 through the air inlet pipe 52, and cold air flows upwards from the bottom of the drying cabinet 1 and is discharged from the air outlet pipe 53, so that the material can contact with the cold air when falling, and further can be cooled more thoroughly.

In the embodiment of the present invention, please refer to fig. 2 and fig. 3, a feed hopper 8 is installed at the top of the drying box 1, a sealing cover 81 is clamped at the top of the feed hopper 8, a discharge pipe 12 is installed at the bottom of the drying box 1, and a valve is installed outside the discharge pipe 12;

it should be noted that: at first with the microbial degradation material and the feed ingredient of drying put into feeder hopper 8 in and close sealed lid 81, can make things convenient for the material earlier on the material falls a set of first water-cooling baffle 22, and when the material fell the bottom of drying cabinet 1, can open the valve on discharging pipe 12, let the good material of cooling discharge from discharging pipe 12 and collect.

The working principle of the efficient cooling device for the feed raw material fermentation powder material provided by the utility model is as follows: firstly, putting dried microbial degradation substances and feed raw materials into a feed hopper 8, then closing a sealing cover 81, so that the materials fall onto a group of first water-cooling partition plates 22 conveniently, starting a refrigerating unit 41 at the moment, externally connecting a connecting pipe 42 with a water pump, pumping water into the refrigerating unit 41, cooling the water, then respectively transmitting the cooled water to each group of first water-cooling partition plates 22 and second water-cooling partition plates 32 through a first water inlet pipe 43 and a second water inlet pipe 44, then performing text cooling on the fallen materials through the cooled first water-cooling partition plates 22, and starting a group of third motors 61 to work to drive a group of screw rods 62 to rotate forwards and backwards, because the push plates 63 are not only in threaded connection with the screw rods 62, but also in sliding connection with the inner wall of the drying box 1, the screw rods 62 can drive the push plates 63 to move back and forth when rotating forwards, and back and forth uniformly turn over the materials on the first water-cooling partition plates 22, further facilitating the first water-cooling partition plate 22 to completely cool the material, then after 30 seconds, starting the first motor 21 to work to drive the first water-cooling partition plate 22 with the spread material to turn downwards, allowing the material to fall on the group of second water-cooling partition plates 32 on the other side of the drying box 1 to continue cooling, starting the other group of third motor 61 to work to drive the push plate 63 to uniformly turn the material on the second water-cooling partition plates 32 for convenient cooling, then continuing starting the second motor 31 to work to drive the second water-cooling partition plates 32 to turn downwards after 30 seconds, allowing the material to fall on the next group of first water-cooling partition plates 22 again for further cooling, so that the material can continuously fall on the other group of second water-cooling partition plates 32 from one group of first water-cooling partition plates 22, then fall on the other group of first water-cooling partition plates 22 from one group of second water-cooling partition plates 32, and sequentially circulate and cool the material, finally, the materials fall to the bottom of the drying box 1, and then the materials can be cooled for multiple times, so that the materials can be cooled to prevent the materials from caking due to overhigh temperature, and when the materials fall from the first water-cooling partition plate 22 to the second water-cooling partition plate 32 or fall from the second water-cooling partition plate 32 to the first water-cooling partition plate 22, the fan 51 can be started to work, air is sucked into the refrigerating unit 41 to be cooled and then blown into the drying box 1 through the air inlet pipe 52, cold air flows upwards from the bottom of the drying box 1 and is discharged from the air outlet pipe 53, so that the materials can be contacted with the cold air when falling, further the materials can be cooled more thoroughly, when the materials fall to the bottom of the drying box 1, the valve on the material outlet pipe 12 can be opened, the cooled materials are discharged from the material outlet pipe 12 to be collected, and the dried microbial degradation materials and feed raw materials can be rapidly cooled, prevent the material from caking due to overhigh temperature.

The circuits and controls involved in the present invention are prior art and will not be described in detail herein.

The above description is only an embodiment of the present invention, and not intended to limit the scope of the present invention, and all modifications of equivalent structures and equivalent processes, which are made by using the contents of the present specification and the accompanying drawings, or directly or indirectly applied to other related technical fields, are included in the scope of the present invention.

Claims (8)

1. The utility model provides a fermented feed raw materials high-efficient cooling device which characterized in that includes:

the drying box comprises a drying box (1), wherein a supporting plate (11) is fixedly installed on the side wall of the drying box (1), and a supporting frame (7) is fixedly installed at the bottom of the supporting plate (11);

the first discharging mechanism (2) is used for placing materials, and the first discharging mechanism (2) is arranged on the inner wall of one end of the drying box (1);

the second discharging mechanism (3) is used for receiving the materials falling from the first discharging mechanism (2), and the second discharging mechanism (3) is arranged on the inner wall of the other end of the drying box (1);

the water cooling mechanism (4) is used for cooling the first discharging mechanism (2) and the second discharging mechanism (3), and the water cooling mechanism (4) is arranged on the supporting plate (11);

the air cooling mechanism (5) is used for cooling the inside of the drying box (1), and the air cooling mechanism (5) is also arranged on the supporting plate (11);

and the tiling mechanism (6) is used for uniformly turning the materials on the first discharging mechanism (2) and the second discharging mechanism (3) and is arranged on the inner walls of the two sides of the drying box (1).

2. The fermented feed raw material efficient cooling device is characterized in that the first discharging mechanism (2) comprises a first motor (21) and a first water-cooling partition plate (22), the first motor (21) is fixedly installed on the outer wall of the drying box (1), one end of the first water-cooling partition plate (22) is rotatably connected with the inner wall of one side of the drying box (1), and the other end of the first water-cooling partition plate (22) is fixedly connected with the output end of the first motor (21).

3. The fermented feed raw material efficient cooling device is characterized in that the second discharging mechanism (3) comprises a second motor (31) and a second water-cooling partition plate (32), the second motor (31) is fixedly installed on the outer wall of the drying box (1), two ends of the second water-cooling partition plate (32) are rotatably connected with the inner wall of one side of the drying box (1), and the other end of the second water-cooling partition plate (32) is fixedly connected with the output end of the second motor (31).

4. The fermented feed raw material efficient cooling device is characterized in that the first discharging mechanism (2) and the second discharging mechanism (3) are provided with a plurality of groups, and the plurality of groups of the first discharging mechanism (2) and the second discharging mechanism (3) are distributed on the inner walls of the two sides of the drying box (1) in a staggered mode.

5. The fermented feed raw material efficient cooling device is characterized in that the water cooling mechanism (4) comprises a refrigerating unit (41), a connecting pipe (42), a first water inlet pipe (43) and a second water inlet pipe (44), the refrigerating unit (41) is fixedly installed at the top of the supporting plate (11), the connecting pipe (42) is connected with the water inlet end of the refrigerating unit (41), the second water inlet pipe (44) is connected between a group of water outlet ends of the refrigerating unit (41) and the first water cooling partition plates (22), and the second water inlet pipe (44) is connected between the other group of water outlet ends of the refrigerating unit (41) and the second water cooling partition plates (32).

6. The efficient cooling device for the fermented feed raw material according to claim 3, characterized in that the tiling mechanism (6) comprises a third motor (61), a lead screw (62) and a push plate (63), a plurality of groups of third motors (61) are arranged on the outer walls of the two ends of the drying box (1), the output end of the third motor (61) is fixedly installed with the lead screw (62) at the output end inside the drying box (1), and the lead screw (62) is arranged above the first water-cooling partition plate (22) and the second water-cooling partition plate (32) respectively, the push plate (63) is connected to the rod wall of the lead screw (62) through threads, and the push plate (63) is further connected with the inner side wall of the drying box (1) in a sliding manner.

7. The fermented feed raw material efficient cooling device is characterized in that the air cooling mechanism (5) comprises a fan (51), an air inlet pipe (52) and an air outlet pipe (53), the fan (51) is connected with an air inlet of the refrigerating unit (41), the air inlet pipe (52) is connected between an air outlet end of the refrigerating unit (41) and the drying box (1), and the air outlet pipe (53) is installed at the top of the drying box (1).

8. The fermented feed raw material efficient cooling device is characterized in that a feed hopper (8) is installed at the top of the drying box (1), a sealing cover (81) is clamped at the top of the feed hopper (8), a discharge pipe (12) is installed at the bottom of the drying box (1), and a valve is installed outside the discharge pipe (12).

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