CN111992168A

CN111992168A - Fat powder extraction processing apparatus

Info

Publication number: CN111992168A
Application number: CN202010926203.9A
Authority: CN
Inventors: 黄跃卿
Original assignee: Individual
Current assignee: Individual
Priority date: 2020-09-07
Filing date: 2020-09-07
Publication date: 2020-11-27

Abstract

The invention relates to the field of fat powder, in particular to a fat powder extraction and treatment device. The technical problem to be solved by the invention is as follows: provided is a fat powder extraction processing device. The technical scheme of the invention is as follows: a fat powder extraction processing device comprises a pressurization and fragmentation mechanism, a reaction extraction mechanism, a draining mechanism, a conveyor belt and the like; the lower part of the first machine bedplate is welded with the first support leg; the first machine tool plate is connected with the second machine tool plate. The invention realizes the fragmentation of soybean oil cakes which are byproducts of oil extraction, extracts and separates the effective oil and fat components in the soybean dregs again in a water flow scouring mode to obtain the soybean dregs with lower oil and fat content for feed production, discharges water in a layered liquid separation mode, and then extracts the soybean phospholipid serving as the raw material of the fat powder from the oil left on the upper layer to obtain the effects of extracting the soybean phospholipid serving as the raw material of the fat powder and the soybean dregs with lower oil and fat content.

Description

Fat powder extraction processing apparatus

Technical Field

The invention relates to the field of fat powder, in particular to a fat powder extraction and treatment device.

Background

The fat powder is powder prepared by taking refined hydrogenated vegetable oil and various food auxiliary materials as raw materials and performing blending, emulsification, sterilization and spray drying.

At present, the main byproduct after oil extraction of soybean is soybean oil cake, the soybean oil cake is often used as feed in the prior art, but raw material soybean phospholipid for producing fat powder still remains in the soybean oil cake, part of which exists in the soybean oil cake in a solid form, thereby leading the soybean oil cake to be directly crushed and put into feed production, the feed contains a large amount of soybean phospholipids, so that fat components in the feed can be increased, nutrient components in the feed are unbalanced, the fat content in meat of livestock can be increased after the livestock eat the feed, and lean meat in the meat of the livestock cannot reach the standard, meanwhile, when the soybean lecithin is extracted from the soybean oil cake, after the soybean oil cake is pressed by high pressure, the soybean dregs are tightly condensed together to form a plate-shaped hard block, which is difficult to be crushed into powder with smaller grain diameter, and the operation of dissolution and extraction cannot be carried out, thus being inconvenient for extracting the soybean phospholipid.

In order to solve the problems, a fat powder extraction and treatment device is provided.

Disclosure of Invention

In order to overcome the defect that the soybean oil cake is often used as feed, but raw material soybean phospholipid for producing fat powder still remains in the soybean oil cake, part of which exists in the soybean oil cake in a solid form, thereby leading the soybean oil cake to be directly crushed and put into feed production, the feed contains a large amount of soybean phospholipids, so that fat components in the feed can be increased, nutrient components in the feed are unbalanced, the fat content in meat of livestock can be increased after the livestock eat the feed, and lean meat in the meat of the livestock cannot reach the standard, meanwhile, when the soybean lecithin is extracted from the soybean oil cake, after the soybean oil cake is pressed by high pressure, the soybean dregs are tightly condensed together to form a plate-shaped hard block, the hard block is difficult to be crushed into powder with smaller grain diameter, the operation of dissolution and extraction cannot be carried out, and the soybean phospholipid extraction is inconvenient to carry out, and the technical problems to be solved by the invention are as follows: provided is a fat powder extraction processing device.

The technical scheme of the invention is as follows: a fat powder extraction processing device comprises a first machine bed plate, a first support column, an operation control screen, a second machine bed plate, a second support column, a pressurizing and smashing mechanism, a reaction extraction mechanism, a draining mechanism and a conveying belt; the lower part of the first machine bedplate is welded with the first support leg; the first machine tool plate is connected with the second machine tool plate; an operation control screen is arranged above the first machine bed board; the upper part of the first machine bed plate is connected with a draining mechanism; the lower part of the second machine tool plate is welded with the second support leg column; the upper part of the second machine tool plate is connected with the reaction extraction mechanism; the reaction extraction mechanism is connected with the draining mechanism; the draining mechanism is connected with the pressurizing and crushing mechanism; the draining mechanism is connected with the second machine tool plate; the draining mechanism is connected with the second support leg column; the lower part of the pressure crushing mechanism is connected with the reaction extraction mechanism; the pressure crushing mechanism is connected with the conveying belt.

In one embodiment, the pressurizing and crushing mechanism comprises a first connecting frame, a crushing cabin, a first driving wheel, a first screw rod, an internal thread sliding plate, a limiting sliding column, a lower pressing plate, a second driving wheel, a first rotating shaft rod, a first bevel gear, a second bevel gear, a rotating track disc, a sliding pushing column, a second connecting frame, a first spray head, a third connecting frame, a first connecting column, a limiting convex column, a sliding rectangular frame, a first connecting plate, an elastic telescopic rod and a lower pressing and bearing plate; the lower part of the first connecting frame is connected with the crushing cabin; the first connecting frame is connected with the first driving wheel; the lower axis of the first driving wheel is rotationally connected with the first screw rod; the lower part of the first screw rod is spliced with the first connecting frame; the outer surface of the first screw rod is in sliding connection with the internal thread sliding plate; the inner side of the internal thread sliding plate is connected with the limiting sliding column in a sliding manner; the limiting sliding column is inserted into the first connecting frame; the lower part of the internal thread sliding plate is inserted with the lower pressing plate; the lower pressing plate is connected with the crushing cabin in a sliding manner; the outer ring surface of the first driving wheel is in transmission connection with the second driving wheel through a belt; the lower axis of the second transmission wheel is rotationally connected with the first rotating shaft rod; the outer surface of the first rotating shaft rod is connected with the first connecting frame; the lower part of the first connecting frame is rotationally connected with a first bevel gear; the first bevel gear is meshed with the second bevel gear; the second bevel gear is connected with the crushing cabin; the rear side of the outer ring surface of the second bevel gear is in transmission connection with a rotating track disc through a belt; the rotating track disc is connected with the second connecting frame; the second connecting frame is connected with the crushing cabin through bolts; the second connecting frame is spliced with the first spray head; the rotating track disc is in sliding connection with the sliding propelling column; the sliding pushing column is inserted with the lower pressing bearing plate; the pressing bearing plate is connected with the second connecting frame in a sliding mode; the pressing bearing plate is inserted into the first connecting column; the first connecting column is inserted with the limiting convex column; the outer surface of the limiting convex column is in sliding connection with the sliding rectangular frame; the sliding rectangular frame is connected with the third connecting frame; the third connecting frame is connected with the crushing cabin; the first connecting column is spliced with the first connecting plate; the first connecting plate is spliced with the elastic telescopic rod; the outer surface of the first connecting plate is in sliding connection with the third connecting frame; the lower part of the second connecting frame is connected with the reaction extraction mechanism; the lower part of the third connecting frame is connected with the reaction extraction mechanism; the elastic telescopic rod is connected with the reaction extraction mechanism; the lower part of the rotating track disc is connected with a draining mechanism; the upper part of the third connecting frame is connected with the conveying belt.

In one embodiment, the reaction extraction mechanism comprises a reaction cabin, a rotary distance meter, a second rotating shaft rod, a first flat gear, a toothed rail, a floating ball, a strip-shaped sliding rail, an electric push rod, a solution spray head, a liquid inlet hose, a liquid outlet valve, a stirring fan blade, a third driving wheel, an inclined blanking screen plate, an electric telescopic valve, a second spray head and a stirring control mechanism; the reaction cabin is connected with the rotary distance measuring instrument; the rotary distance measuring instrument is rotatably connected with the second rotating shaft rod; the second rotating shaft rod is in rotating connection with the first flat gear; the outer surface of the second rotating shaft rod is connected with the reaction cabin; the first flat gear is meshed with the rack; the lower part of the rack is connected with a floater ball; the toothed rail is in sliding connection with the strip-shaped sliding rail; the upper part of the strip-shaped slide rail is inserted into the reaction cabin; the reaction cabin is connected with the electric push rod; the lower part of the electric push rod is connected with a solution spray head; the solution nozzle is inserted into the liquid inlet hose; the outer surface of the liquid inlet hose is connected with the reaction cabin; the reaction cabin is connected with a liquid discharge valve; the reaction cabin is spliced with the stirring fan blades; the axle center of the stirring fan blade is rotationally connected with the third driving wheel; the outer ring surface of the third driving wheel is in transmission connection with the stirring control mechanism through a belt; the stirring control mechanism is inserted with the reaction cabin; an inclined blanking screen plate is arranged on the inner side of the reaction cabin; a second spray head is arranged on the inner side of the reaction cabin; the reaction cabin is connected with an electric telescopic valve; the stirring control mechanism is connected with the third connecting frame; the stirring control mechanism is connected with the elastic telescopic rod; the upper part of the reaction cabin is connected with a second connecting frame; the upper part of the reaction cabin is connected with a third connecting frame; the lower part of the reaction cabin is connected with a second machine tool plate; the reaction cabin is connected with a draining mechanism.

In one embodiment, the draining mechanism comprises a power motor, a fourth driving wheel, a motor plate, a fifth driving wheel, a sixth driving wheel, a connecting column, a rotating deflector rod, a sliding lifting convex column, a special-shaped sliding rail plate, a sliding lifting rod, a vibrating ball, a multi-layer soft filter screen, a bearing sliding frame, a supporting sliding rail frame, a linkage rod, a rotating disc, a collecting box and a seventh driving wheel; an output shaft of the power motor is rotationally connected with the fourth transmission wheel; the lower part of the power motor is connected with a motor plate through a bolt; the outer ring surface of the fourth driving wheel is in transmission connection with the fifth driving wheel through a belt; the outer ring surface of the fourth driving wheel is in transmission connection with the seventh driving wheel through a belt; the fifth driving wheel is connected with the motor plate; the outer ring surface of the fifth driving wheel is in transmission connection with the sixth driving wheel through a belt; the front side of the outer surface of the sixth driving wheel is spliced with the connecting column; the axis of the sixth driving wheel is rotationally connected with the rotating deflector rod; the rotating deflector rod is inserted with the sliding lifting convex column; the sliding lifting convex column is in sliding connection with the special-shaped sliding rail plate; the upper part of the special-shaped slide rail plate is inserted with the sliding lifting rod; the sliding lifting rod is inserted with the vibrating ball; a plurality of layers of soft filter screens are arranged above the vibrating ball; the multilayer soft filter screen is connected with the bearing sliding frame; the bearing sliding frame is in sliding connection with the supporting sliding rail frame; the bearing sliding frame is rotatably connected with the linkage rod; the linkage rod is rotationally connected with the rotating disc; a collecting box is arranged below the multi-layer soft filter screen; the lower part of the collecting box is connected with a first bed board; the rotating disc is connected with the reaction cabin; the lower part of the support slide rail frame is connected with a first machine bedplate; the outer surface of the sliding lifting rod is connected with the first bed board; the connecting column is connected with the first machine bed plate; the motor plate is connected with the second support leg column; the seventh transmission wheel is connected with the second machine tool plate; the seventh driving wheel is connected with the rotating track disc.

In one embodiment, the stirring control mechanism comprises a bearing sleeve column, an eighth transmission wheel, a shifting block, an electric shifting plate, an engaging spinning sleeve and a screw rod; the bearing sleeve column is inserted with the eighth transmission wheel through a bearing; the eighth driving wheel is connected with the shifting block; the shifting block is in transmission connection with the electric shifting plate; the eighth transmission wheel is rotationally connected with the meshing self-rotating sleeve; the inner side of the meshing self-rotating sleeve is meshed with the screw; the screw rod is connected with the elastic telescopic rod; the electric toggle plate is connected with the third connecting frame; the bearing sleeve column is connected with the reaction cabin; the eighth driving wheel is connected with the third driving wheel.

In one embodiment, the upper part of the pressing bearing plate is a slope with a lower left part and a higher right part.

In one embodiment, a stop is provided on the left side of the top end of the push down carrier plate.

In one embodiment, a groove is arranged in the middle of the bottom end in the reaction chamber, and the bottom of the solution spray head is in contact with the bottom of the groove.

In one embodiment, the bottom of the right end of the reaction cabin is provided with a transparent observation window.

Compared with the prior art, the invention has the following advantages: the soybean oil cake is used as a feed, but raw material soybean phospholipid capable of producing fat powder still remains in the soybean oil cake, part of the soybean phospholipid exists in the soybean oil cake in a solid form, so that the soybean oil cake is directly crushed and put into feed production, the soybean oil cake internally contains a large amount of soybean phospholipid, fat components in the feed can be increased, nutrient components in the feed are unbalanced, the fat content in meat quality of livestock can be increased after the livestock eat the soybean oil cake, lean meat in the meat quality of the livestock cannot reach the standard, and meanwhile, when the soybean phospholipid is extracted from the soybean oil cake, soybean residues are tightly condensed together to form plate-shaped hard blocks after the soybean oil cake is pressed by high pressure, the soybean oil cake is difficult to be crushed into powder with small particle size, the operation of dissolution extraction cannot be carried out, and the extraction of the soybean phospholipid is inconvenient;

the method is characterized in that a pressurizing and smashing mechanism, a reaction and extraction mechanism and a reaction and extraction mechanism are designed, when the method is used, firstly, the pressurizing and smashing mechanism smashes soybean oil cakes, soaking operation is carried out in the smashing process, smashed soybean residues are soaked through water, effective oil and fat components in the smashed soybean residues are subjected to solution extraction, then most of solution enters the reaction and extraction mechanism, meanwhile, the soybean residues and part of water enter the reaction and extraction mechanism for draining operation, purer soybean residues are obtained, meanwhile, the water and the oil entering the reaction and extraction mechanism are layered, then the water below the reaction and extraction mechanism is discharged, and then reaction liquid is added to extract fat powder from mixed oil;

the method has the advantages that the soybean oil cake as the byproduct of oil extraction is crushed, the flaky concentrated and compact and hard soybean oil cake is sufficiently crushed, the effective oil and fat components in the soybean residue are extracted and separated again in a water flow flushing mode, the soybean residue with lower oil and fat content is obtained and used for feed production, water is discharged in a layering and liquid separating mode, then the extraction operation of the soybean phospholipid as the raw material of the fat powder is carried out on the oil left on the upper layer, and the effects of extracting the soybean phospholipid as the raw material of the fat powder and the soybean residue with lower oil and fat content are obtained.

Drawings

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

FIG. 2 is a schematic view of the pressure reducing mechanism of the present invention;

FIG. 3 is a schematic view of the structure of the reaction extraction mechanism of the present invention;

FIG. 4 is a schematic structural view of a draining mechanism of the present invention;

FIG. 5 is a schematic structural diagram of a stirring control mechanism according to the present invention.

In the figure: 1. a first machine bed board, 2, a first support leg, 3, an operation control screen, 4, a second machine bed board, 5, a second support leg, 6, a pressurization fragmentation mechanism, 7, a reaction extraction mechanism, 8, a draining mechanism, 9, a conveyor belt, 601, a first connecting frame, 602, a fragmentation cabin, 603, a first driving wheel, 604, a first screw rod, 605, an internal thread sliding plate, 606, a limit sliding column, 607, a lower pressing plate, 608, a second driving wheel, 609, a first rotating shaft rod, 6010, a first bevel gear, 6011, a second bevel gear, 6012, a rotating track disc, 6013, a sliding propulsion column, 6014, a second connecting frame, 6015, a first nozzle, 6016, a third connecting frame, 6017, a first connecting column, 6018, a limit convex column, 6019, a sliding rectangular frame, 6020, a first connecting plate, 6021, an elastic telescopic rod, 6022, a lower pressing bearing plate, 701, a reaction cabin, 702, a rotating distance meter, 703 and a second rotating distance meter, 704. a first flat gear, 705, a rack, 706, a floater ball, 707, a strip-shaped sliding rail, 708, an electric push rod, 709, a solution spray head, 7010, a liquid inlet hose, 7011, a liquid discharging valve, 7012, a stirring fan blade, 7013, a third driving wheel, 7014, an inclined blanking screen plate, 7015, an electric telescopic valve, 7016, a second spray head, 7017, a stirring control mechanism, 801, a power motor, 802, a fourth driving wheel, 803, a motor plate, 804, a fifth driving wheel, 805, a sixth driving wheel, 806, a connecting column, 807, a rotating deflector rod, 808, a sliding lifting convex column, 809, a special-shaped sliding rail plate, 8010, a sliding lifting rod, 8011, a vibrating ball, 8012, a multi-layer soft filter screen, 8013, a bearing sliding frame, 8014, a supporting sliding rail frame, 8015, a linkage rod, 8016, a rotating disc, 8017, a collecting box, 8018, a seventh, 701701, a bearing column, 701702, an eighth sleeve block, 701703, a moving block, 701704, a driving wheel, a shifting, An electric toggle plate 701705, an engaged spinning sleeve 701706 and a screw rod.

Detailed Description

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

Example 1

A fat powder extraction processing device is shown in figures 1-5, and comprises a first machine bed plate 1, a first support column 2, an operation control screen 3, a second machine bed plate 4, a second support column 5, a pressurizing and smashing mechanism 6, a reaction extraction mechanism 7, a draining mechanism 8 and a conveyor belt 9; the lower part of the first machine bed plate 1 is welded with the first support leg 2; the first machine bed board 1 is connected with the second machine bed board 4; an operation control screen 3 is arranged above the first machine bed board 1; the upper part of the first machine bed plate 1 is connected with a draining mechanism 8; the lower part of the second machine tool plate 4 is welded with a second support leg column 5; the upper part of the second machine bed plate 4 is connected with a reaction extraction mechanism 7; the reaction extraction mechanism 7 is connected with a draining mechanism 8; the draining mechanism 8 is connected with the pressurizing and crushing mechanism 6; the draining mechanism 8 is connected with the second machine bed plate 4; the draining mechanism 8 is connected with the second support pillar 5; the lower part of the pressurization and fragmentation mechanism 6 is connected with a reaction extraction mechanism 7; the pressure reducing mechanism 6 is connected to a conveyor belt 9.

When the fat powder extraction and treatment device is used, the device is stably fixed to a working plane, then a power supply is connected externally, an operation control screen 3 is manually opened, then a power system in the device is connected through the operation control screen 3, then soybean oil cakes are conveyed to the inside of a pressurizing and smashing mechanism 6 through a conveyor belt 9, then the pressurizing and smashing mechanism 6 smashes the soybean oil cakes, soaking operation is carried out in the smashing process, smashed soybean residues are soaked through water, effective oil and fat components in the smashed soybean residues are extracted through solution, then most of the solution enters a reaction extraction mechanism 7, meanwhile, the soybean residues and part of water enter a draining mechanism 8 for draining operation, purer soybean residues are obtained, meanwhile, the water and the oil entering the reaction extraction mechanism 7 are layered, the water below is discharged, then reaction liquid is added to extract fat powder from mixed oil, the method has the advantages that the soybean oil cake as the byproduct of oil extraction is crushed, the flaky concentrated and compact and hard soybean oil cake is sufficiently crushed, the effective oil and fat components in the soybean residue are extracted and separated again in a water flow flushing mode, the soybean residue with lower oil and fat content is obtained and used for feed production, water is discharged in a layering and liquid separating mode, then the extraction operation of the soybean phospholipid as the raw material of the fat powder is carried out on the oil left on the upper layer, and the effects of extracting the soybean phospholipid as the raw material of the fat powder and the soybean residue with lower oil and fat content are obtained.

The pressurizing and crushing mechanism 6 comprises a first connecting frame 601, a crushing cabin 602, a first driving wheel 603, a first screw rod 604, an internal thread sliding plate 605, a limiting sliding column 606, a lower pressing plate 607, a second driving wheel 608, a first rotating shaft 609, a first bevel gear 6010, a second bevel gear 6011, a rotating track disc 6012, a sliding pushing column 6013, a second connecting frame 6014, a first nozzle 6015, a third connecting frame 6016, a first connecting column 6017, a limiting convex column 6018, a sliding rectangular frame 6019, a first connecting plate 6020, an elastic telescopic rod 6021 and a lower pressing bearing plate 6022; the lower part of the first connecting frame 601 is connected with the reducing cabin 602; the first connecting frame 601 is connected with the first driving wheel 603; the axle center below the first driving wheel 603 is rotationally connected with the first screw rod 604; the lower part of the first screw rod 604 is inserted into the first connecting frame 601; the outer surface of the first screw rod 604 is in sliding connection with the internal thread sliding plate 605; the inner side of the internal thread sliding plate 605 is in sliding connection with the limiting sliding column 606; the limiting sliding column 606 is inserted into the first connecting frame 601; the lower part of the internal thread sliding plate 605 is inserted into the lower pressure plate 607; the lower pressing plate 607 is slidably connected with the reduction chamber 602; the outer ring surface of the first driving wheel 603 is in driving connection with a second driving wheel 608 through a belt; the axle center below the second driving wheel 608 is rotationally connected with a first rotating shaft rod 609; the outer surface of the first rotating shaft 609 is connected with the first connecting frame 601; the lower part of the first connecting frame 601 is rotatably connected with a first bevel gear 6010; the first bevel gear 6010 is engaged with the second bevel gear 6011; the second bevel gear 6011 is connected with the reducing cabin 602; the rear side of the outer annular surface of the second bevel gear 6011 is in transmission connection with a rotating track disc 6012 through a belt; the rotating track disc 6012 is connected to a second link 6014; the second connecting frame 6014 is bolted to the size reduction chamber 602; the second connecting frame 6014 is inserted into the first nozzle 6015; the rotating track disc 6012 is slidably connected to a sliding propulsion column 6013; the sliding propulsion column 6013 is inserted into the lower pressure bearing plate 6022; the lower pressing bearing plate 6022 is slidably connected with the second connecting frame 6014; the bearing plate 6022 is pressed down to be inserted into the first connecting column 6017; the first joining column 6017 is spliced with the limiting convex column 6018; the outer surface of the limiting convex column 6018 is in sliding connection with a sliding rectangular frame 6019; the sliding rectangular frame 6019 is connected to a third link 6016; the third connecting frame 6016 is connected to the fragmentation cell 602; the first connecting column 6017 is spliced with the first connecting plate 6020; the first connecting plate 6020 is spliced with the elastic telescopic rod 6021; the outer surface of the first joint plate 6020 is slidably connected to the third connecting frame 6016; the lower part of the second connecting frame 6014 is connected with a reaction extraction mechanism 7; the lower part of the third connecting frame 6016 is connected with the reaction extraction mechanism 7; the elastic telescopic rod 6021 is connected with the reaction extraction mechanism 7; the lower part of the rotating track disc 6012 is connected with a draining mechanism 8; the third connecting frame 6016 is connected to the conveyor belt 9 above.

Firstly, a conveyor belt 9 drives soybean oil cakes to enter a smashing cabin 602, the soybean oil cakes are accumulated above a lower pressure bearing plate 6022, then a seventh driving wheel 8018 drives a rotating track disc 6012 to rotate, then the rotating track disc 6012 drives a second bevel gear 6011 to rotate, then the second bevel gear 6011 drives a first bevel gear 6010 to rotate, then the first bevel gear 6010 drives a first rotating shaft rod 609 to rotate, then the first rotating shaft rod 609 drives a second driving wheel 608 to rotate, and then the second driving wheel 608 drives a first driving wheel 603 to be in transmission connection; the first driving wheel 603 drives the first lead screw 604 to rotate, and then the first lead screw 604 rotates to drive the internal thread sliding plate 605 to move downwards, and then the internal thread sliding plate 605 slides downwards on the surface of the limit sliding column 606, and then the internal thread sliding plate 605 drives the lower pressing plate 607 to slide downwards on the inner side of the fragmentation cabin 602, and then the lower pressing plate 607 moves to press downwards above the soybean oil cake above the lower pressing bearing plate 6022, and then the lower pressing plate 607 continues to press downwards to crush the soybean oil cake, and simultaneously the rotating track disc 6012 rotates, the sliding pushing column 6013 slides inside the rotating track disc 6012, and then the rotating track disc 6012 drives the lower pressing bearing plate 6022 to slide left and right through the sliding pushing column 6013, and at the same time the lower pressing bearing plate 6022 drives the limit protruding column 6018 to slide on the inner side of the sliding rectangular frame 6019 through the first linking column 6017, and the first linking column 6010 drives the first linking plate 6020 to slide left and right inside the third linking frame 6016, when the soybean oil cake above the pressing-down bearing plate 6022 is pressurized by the pressing-down plate 607, the pressing-down bearing plate 6022 is shaken left and right to accelerate the pulverization of the soybean oil cake, then the water is sprayed by the first nozzle 6015, the soybean residue above the pressing-down bearing plate 6022 is washed leftwards, and then the soybean residue and the liquid mixture drop into the reaction chamber 701 from the left opening above the pressing-down bearing plate 6022, so that the sufficient pulverization of the soybean oil cake is completed.

Wherein, the reaction extraction mechanism 7 comprises a reaction cabin 701, a rotary distance meter 702, a second rotating shaft rod 703, a first pinion 704, a rack 705, a floater 706, a strip-shaped slide rail 707, an electric push rod 708, a solution spray head 709, a liquid inlet hose 7010, a liquid outlet valve 7011, a stirring fan 7012, a third driving wheel 7013, an inclined blanking screen 7014, an electric telescopic valve 7015, a second spray head 7016 and a stirring control mechanism 7017; the reaction cabin 701 is connected with a rotary distance meter 702; the rotary distance measuring instrument 702 is rotatably connected with the second rotating shaft rod 703; the second rotating shaft 703 is rotationally connected with the first pinion 704; the outer surface of the second rotating shaft rod 703 is connected with the reaction cabin 701; the first pinion 704 meshes with the rack 705; the lower part of the rack 705 is connected with a float ball 706; the rack 705 is connected with a strip-shaped slide rail 707 in a sliding way; the upper part of the strip-shaped sliding rail 707 is inserted into the reaction cabin 701; the reaction cabin 701 is connected with an electric push rod 708; the lower part of the electric push rod 708 is connected with a solution spray head 709; the solution spray head 709 is inserted into the liquid inlet hose 7010; the outer surface of the liquid inlet hose 7010 is connected with the reaction cabin 701; the reaction cabin 701 is connected with a liquid discharge valve 7011; the reaction cabin 701 is spliced with the stirring fan 7012; the axle center of the stirring fan blade 7012 is rotationally connected with a third driving wheel 7013; the outer ring surface of the third driving wheel 7013 is in driving connection with a stirring control mechanism 7017 through a belt; the stirring control mechanism 7017 is inserted into the reaction cabin 701; an inclined blanking screen plate 7014 is arranged on the inner side of the reaction cabin 701; a second spray head 7016 is arranged on the inner side of the reaction cabin 701; the reaction cabin 701 is connected with an electric telescopic valve 7015; the stirring control mechanism 7017 is connected with the third connecting frame 6016; the stirring control mechanism 7017 is connected with the elastic telescopic rod 6021; the upper part of the reaction cabin 701 is connected with a second connecting frame 6014; the upper part of the reaction cabin 701 is connected with a third connecting frame 6016; the lower part of the reaction cabin 701 is connected with a second machine bed plate 4; the reaction cabin 701 is connected with a draining mechanism 8.

Firstly, an electric telescopic valve 7015 is controlled to be opened by an operation control screen 3, then soybean dregs and a liquid mixture fall to the upper part of an inclined blanking screen plate 7014, water is sprayed to the upper part of meshes of the inclined blanking screen plate 7014 through a second spray head 7016, then water flow drives the soybean dregs to slide down to the inside of a draining mechanism 8 from the left side of the inclined blanking screen plate 7014 again, simultaneously mixed liquid components of water and oil enter the inside of a reaction cabin 701, then a float ball 706 is subjected to the buoyancy of the liquid, and then the float ball 706 drives a rack 705 to move upwards, then the rack 705 drives a first pinion 704 to rotate, and then the first pinion 704 rotates to drive a second rotating shaft rod 703 to rotate, and then the second rotating shaft rod rotates at the inner side of a rotation distance meter 702, then the rotation distance meter 702 records the floating distance of the float ball 706 according to the number of rotation turns of the first pinion 704, and then the water and grease in the reaction cabin, then the grease is positioned above the water layer, then the liquid discharging valve 7011 is manually opened, then the water layer below the inner part of the reaction chamber 701 is discharged from the opening of the liquid discharging valve 7011, then the liquid level descends, the floater ball 706 descends along with the descending, at the moment, the distance measuring instrument 702 is rotated to record the moving distance of the floater ball 706 again, then the distance measuring instrument 702 is rotated to obtain the height of the residual oil layer, then the distance measuring instrument 702 is rotated to transmit the data to the electric push rod 708, then the electric push rod 708 drives the solution spray head 709 to contract to the ascending distance equal to the high speed of the oil layer, and the fat powder extraction reaction liquid is added through the liquid inlet hose 7010, the reaction with the grease mixture is completed after being sprayed out from the solution spray head 709, meanwhile, the elastic telescopic rod 6021 moves left and right to drive the stirring control mechanism 7017 to rotate, then the stirring control mechanism 7017 drives the, then the stirring fan 7012 rotates to accelerate the reaction in the reaction cabin 701, thereby completing the reaction extraction of the fat powder.

The draining mechanism 8 comprises a power motor 801, a fourth driving wheel 802, a motor plate 803, a fifth driving wheel 804, a sixth driving wheel 805, a connecting column 806, a rotating driving lever 807, a sliding lifting convex column 808, a special-shaped sliding rail plate 809, a sliding lifting rod 8010, a vibrating ball 8011, a multi-layer soft filter screen 8012, a bearing sliding frame 8013, a supporting sliding rail frame 8014, a linkage rod 8015, a rotating disc 8016, a collecting box 8017 and a seventh driving wheel 8018; an output shaft of the power motor 801 is rotationally connected with a fourth transmission wheel 802; the lower part of the power motor 801 is connected with a motor plate 803 through bolts; the outer annular surface of the fourth driving wheel 802 is in transmission connection with the fifth driving wheel 804 through a belt; the outer annular surface of the fourth driving wheel 802 is in driving connection with the seventh driving wheel 8018 through a belt; the fifth driving wheel 804 is connected with the motor plate 803; the outer annular surface of the fifth driving wheel 804 is in transmission connection with a sixth driving wheel 805 through a belt; the front side of the outer surface of the sixth driving wheel 805 is inserted into the connecting column 806; the axis of the sixth driving wheel 805 is rotationally connected with a rotating deflector rod 807; the rotating driving lever 807 is inserted into the sliding lifting convex column 808; the sliding lifting convex columns 808 are in sliding connection with the special-shaped sliding rail plate 809; the upper part of the special-shaped sliding rail plate 809 is spliced with the sliding lifting rod 8010; the sliding lifting rod 8010 is inserted into the vibrating ball 8011; a multi-layer soft filter screen 8012 is arranged above the vibrating ball 8011; the multi-layer soft filter screen 8012 is connected with the bearing sliding frame 8013; the bearing sliding frame 8013 is in sliding connection with the supporting sliding rail frame 8014; the bearing sliding frame 8013 is rotatably connected with the linkage rod 8015; the linkage rod 8015 is rotatably connected with the rotary disc 8016; a collecting box 8017 is arranged below the multi-layer soft filter screen 8012; the lower part of the collecting box 8017 is connected with the first bedplate 1; the rotary disc 8016 is connected with the reaction chamber 701; the lower part of the supporting slide rail frame 8014 is connected with the first bedplate 1; the outer surface of the sliding lifting rod 8010 is connected with the first bedplate 1; the connecting column 806 is connected with the first machine bed board 1; the motor board 803 is connected with the second leg post 5; the seventh driving wheel 8018 is connected with the second bedplate 4; a seventh drive wheel 8018 is coupled to the rotatable track disc 6012.

The soybean dregs and partial water slide from the left side of the inclined blanking screen plate 7014 to the inside of a plurality of layers of soft filter screens 8012, meanwhile, a power motor 801 drives a fourth driving wheel 802 to rotate, then the fourth driving wheel 802 drives a fifth driving wheel 804 to rotate, further the fifth driving wheel 804 drives a sixth driving wheel 805 to rotate, then the sixth driving wheel 805 drives a rotating poking rod 807 to rotate, further the rotating poking rod 807 drives a special-shaped sliding rail plate 809 to move upwards through a sliding lifting convex column 808, then the special-shaped sliding rail plate 809 drives a sliding lifting rod 8010 to move upwards, then the sliding lifting rod 8010 drives a vibrating ball 8011 to move upwards, then the vibrating ball 8011 moves upwards and downwards to drive the plurality of layers of soft filter screens 8012 to vibrate, meanwhile, the sixth driving wheel drives a rotating disc 8016 to rotate, then the rotating disc 8016 drives a linkage rod 8015 to reciprocate left and right, then the linkage rod 8015 drives a bearing sliding frame 3 to slide left and right on the inner side of a, bear carriage 8013 and drive the soft filter screen 8012 of multilayer and carry out reciprocating motion about promptly, vibrate ball 8011 simultaneously and carry out the below vibration to the soft filter screen 8012 of multilayer, and then leak in the inside moisture of the inside soybean sediment of the soft filter screen 8012 of multilayer from the mesh of the soft filter screen 8012 of multilayer, the water droplet falls to collecting box 8017 inside and is collected, has accomplished the waterlogging caused by excessive rainfall operation of soybean sediment, has obtained pure soybean sediment.

Wherein, the stirring control mechanism 7017 comprises a bearing sleeve column 701701, an eighth driving wheel 701702, a shifting block 701703, an electric shifting plate 701704, a meshing spin sleeve 701705 and a screw 701706; the bearing sleeve column 701701 is inserted into the eighth driving wheel 701702 through a bearing; the eighth driving wheel 701702 is connected with the shifting block 701703; the toggle block 701703 is in transmission connection with the electric toggle plate 701704; the eighth driving wheel 701702 is rotatably connected with the meshing spin sleeve 701705; the inner side of the meshing self-rotating sleeve 701705 is meshed with the screw 701706; the screw 701706 is connected with the elastic telescopic rod 6021; the electric driver plate 701704 is connected to the third link 6016; the bearing sleeve column 701701 is connected with the reaction cabin 701; the eighth drive pulley 701702 is connected to the third drive pulley 7013.

Firstly, the elastic expansion link 6021 drives the screw 701706 to move left and right, at this time, the thread of the screw 701706 is engaged with the inner side thread of the engaging self-rotating sleeve 701705, then the screw 701706 moves right in the engaging self-rotating sleeve 701705, at this time, the electric toggle plate 701704 rotates the toggle block 701703, further, the toggle block 701703 drives the eighth transmission wheel 701702 to rotate, further, the eighth transmission wheel 701702 drives the engaging self-rotating sleeve 701705 to perform an initial slight rotation, further, under the thrust of the right movement of the screw 701706, the engaging self-rotating sleeve 701705 is further driven by the eighth transmission wheel 701702 to realize the continuous sliding rotation of the engaging self-rotating sleeve 701705 along the thread of the outer surface of the screw 701706, and similarly, when the screw 701706 moves left, the engaging self-rotating sleeve 701705 and the eighth transmission wheel 701702 are driven to rotate reversely, further, the eighth transmission wheel 701702 drives the stirring fan 7012 to rotate forward and backward through the third transmission.

Wherein, the upper part of the press-down bearing plate 6022 is an inclined plane with a lower left part and a higher right part.

So as to guide water flow to automatically take away the ground soybean dregs by utilizing the inclined state, and avoid the accumulation of the soybean dregs from influencing the subsequent crushing operation.

Wherein, a stop block is arranged at the left side of the top end of the press-down bearing plate 6022.

So as to block the soybean dregs and liquid mixture flowing leftwards at the top end of the press-down bearing plate 6022 and make the soybean dregs and liquid mixture flow out from the opening of the through hole at the right side of the stop block arranged at the left side of the top end of the press-down bearing plate 6022.

Wherein, the middle part of the bottom end in the reaction chamber 701 is provided with a groove, and the bottom of the solution spray head 709 is contacted with the bottom of the groove.

So that after the electric push rod 708 drives the solution nozzle 709 to shrink and rise to a height equal to the thickness of the oil layer, because the bottom of the solution nozzle 709 initially contacts with the bottom of the groove, at this time, a part of the solution nozzle 709 is still under the liquid level of the oil layer and isolated from the air, and the reaction liquid is injected at this time, which can prolong the settling time of the reaction liquid in the oil layer to ensure more sufficient extraction and avoid the volatilization of the reaction liquid.

Wherein, the bottom of the right end of the reaction cabin 701 is provided with a transparent observation window.

So as to visually observe the interface of oil and water inside the reaction tank 701.

While the disclosure has been shown and described with reference to certain exemplary embodiments thereof, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the disclosure as defined by the appended claims and their equivalents. Accordingly, the scope of the present disclosure should not be limited to the above-described embodiments, but should be defined not only by the appended claims, but also by equivalents thereof.

Claims

1. The utility model provides a fat powder draws processing apparatus, includes first bedplate, first socle and operation control screen, characterized by: the device also comprises a second machine bed plate, a second support column, a pressurizing and crushing mechanism, a reaction and extraction mechanism, a draining mechanism and a conveying belt; the lower part of the first machine bedplate is welded with the first support leg; the first machine tool plate is connected with the second machine tool plate; an operation control screen is arranged above the first machine bed board; the upper part of the first machine bed plate is connected with a draining mechanism; the lower part of the second machine tool plate is welded with the second support leg column; the upper part of the second machine tool plate is connected with the reaction extraction mechanism; the reaction extraction mechanism is connected with the draining mechanism; the draining mechanism is connected with the pressurizing and crushing mechanism; the draining mechanism is connected with the second machine tool plate; the draining mechanism is connected with the second support leg column; the lower part of the pressure crushing mechanism is connected with the reaction extraction mechanism; the pressure crushing mechanism is connected with the conveying belt.

2. The fat powder extraction processing device of claim 1, wherein: the pressurizing and crushing mechanism comprises a first connecting frame, a crushing cabin, a first driving wheel, a first screw rod, an internal thread sliding plate, a limiting sliding column, a lower pressing plate, a second driving wheel, a first rotating shaft rod, a first bevel gear, a second bevel gear, a rotating track disc, a sliding propulsion column, a second connecting frame, a first nozzle, a third connecting frame, a first connecting column, a limiting convex column, a sliding rectangular frame, a first connecting plate, an elastic telescopic rod and a lower pressing bearing plate; the lower part of the first connecting frame is connected with the crushing cabin; the first connecting frame is connected with the first driving wheel; the lower axis of the first driving wheel is rotationally connected with the first screw rod; the lower part of the first screw rod is spliced with the first connecting frame; the outer surface of the first screw rod is in sliding connection with the internal thread sliding plate; the inner side of the internal thread sliding plate is connected with the limiting sliding column in a sliding manner; the limiting sliding column is inserted into the first connecting frame; the lower part of the internal thread sliding plate is inserted with the lower pressing plate; the lower pressing plate is connected with the crushing cabin in a sliding manner; the outer ring surface of the first driving wheel is in transmission connection with the second driving wheel through a belt; the lower axis of the second transmission wheel is rotationally connected with the first rotating shaft rod; the outer surface of the first rotating shaft rod is connected with the first connecting frame; the lower part of the first connecting frame is rotationally connected with a first bevel gear; the first bevel gear is meshed with the second bevel gear; the second bevel gear is connected with the crushing cabin; the rear side of the outer ring surface of the second bevel gear is in transmission connection with a rotating track disc through a belt; the rotating track disc is connected with the second connecting frame; the second connecting frame is connected with the crushing cabin through bolts; the second connecting frame is spliced with the first spray head; the rotating track disc is in sliding connection with the sliding propelling column; the sliding pushing column is inserted with the lower pressing bearing plate; the pressing bearing plate is connected with the second connecting frame in a sliding mode; the pressing bearing plate is inserted into the first connecting column; the first connecting column is inserted with the limiting convex column; the outer surface of the limiting convex column is in sliding connection with the sliding rectangular frame; the sliding rectangular frame is connected with the third connecting frame; the third connecting frame is connected with the crushing cabin; the first connecting column is spliced with the first connecting plate; the first connecting plate is spliced with the elastic telescopic rod; the outer surface of the first connecting plate is in sliding connection with the third connecting frame; the lower part of the second connecting frame is connected with the reaction extraction mechanism; the lower part of the third connecting frame is connected with the reaction extraction mechanism; the elastic telescopic rod is connected with the reaction extraction mechanism; the lower part of the rotating track disc is connected with a draining mechanism; the upper part of the third connecting frame is connected with the conveying belt.

3. The fat powder extraction processing device of claim 2, wherein: the reaction extraction mechanism comprises a reaction cabin, a rotary distance meter, a second rotating shaft rod, a first flat gear, a toothed rail, a float ball, a strip-shaped slide rail, an electric push rod, a solution spray nozzle, a liquid inlet hose, a liquid discharge valve, stirring fan blades, a third driving wheel, an inclined discharging screen plate, an electric telescopic valve, a second spray nozzle and a stirring control mechanism; the reaction cabin is connected with the rotary distance measuring instrument; the rotary distance measuring instrument is rotatably connected with the second rotating shaft rod; the second rotating shaft rod is in rotating connection with the first flat gear; the outer surface of the second rotating shaft rod is connected with the reaction cabin; the first flat gear is meshed with the rack; the lower part of the rack is connected with a floater ball; the toothed rail is in sliding connection with the strip-shaped sliding rail; the upper part of the strip-shaped slide rail is inserted into the reaction cabin; the reaction cabin is connected with the electric push rod; the lower part of the electric push rod is connected with a solution spray head; the solution nozzle is inserted into the liquid inlet hose; the outer surface of the liquid inlet hose is connected with the reaction cabin; the reaction cabin is connected with a liquid discharge valve; the reaction cabin is spliced with the stirring fan blades; the axle center of the stirring fan blade is rotationally connected with the third driving wheel; the outer ring surface of the third driving wheel is in transmission connection with the stirring control mechanism through a belt; the stirring control mechanism is inserted with the reaction cabin; an inclined blanking screen plate is arranged on the inner side of the reaction cabin; a second spray head is arranged on the inner side of the reaction cabin; the reaction cabin is connected with an electric telescopic valve; the stirring control mechanism is connected with the third connecting frame; the stirring control mechanism is connected with the elastic telescopic rod; the upper part of the reaction cabin is connected with a second connecting frame; the upper part of the reaction cabin is connected with a third connecting frame; the lower part of the reaction cabin is connected with a second machine tool plate; the reaction cabin is connected with a draining mechanism.

4. The fat powder extraction processing device of claim 3, wherein: the draining mechanism comprises a power motor, a fourth driving wheel, a motor plate, a fifth driving wheel, a sixth driving wheel, a connecting column, a rotating deflector rod, a sliding lifting convex column, a special-shaped sliding rail plate, a sliding lifting rod, a vibrating ball, a multi-layer soft filter screen, a bearing sliding frame, a supporting sliding rail frame, a linkage rod, a rotating disc, a collecting box and a seventh driving wheel; an output shaft of the power motor is rotationally connected with the fourth transmission wheel; the lower part of the power motor is connected with a motor plate through a bolt; the outer ring surface of the fourth driving wheel is in transmission connection with the fifth driving wheel through a belt; the outer ring surface of the fourth driving wheel is in transmission connection with the seventh driving wheel through a belt; the fifth driving wheel is connected with the motor plate; the outer ring surface of the fifth driving wheel is in transmission connection with the sixth driving wheel through a belt; the front side of the outer surface of the sixth driving wheel is spliced with the connecting column; the axis of the sixth driving wheel is rotationally connected with the rotating deflector rod; the rotating deflector rod is inserted with the sliding lifting convex column; the sliding lifting convex column is in sliding connection with the special-shaped sliding rail plate; the upper part of the special-shaped slide rail plate is inserted with the sliding lifting rod; the sliding lifting rod is inserted with the vibrating ball; a plurality of layers of soft filter screens are arranged above the vibrating ball; the multilayer soft filter screen is connected with the bearing sliding frame; the bearing sliding frame is in sliding connection with the supporting sliding rail frame; the bearing sliding frame is rotatably connected with the linkage rod; the linkage rod is rotationally connected with the rotating disc; a collecting box is arranged below the multi-layer soft filter screen; the lower part of the collecting box is connected with a first bed board; the rotating disc is connected with the reaction cabin; the lower part of the support slide rail frame is connected with a first machine bedplate; the outer surface of the sliding lifting rod is connected with the first bed board; the connecting column is connected with the first machine bed plate; the motor plate is connected with the second support leg column; the seventh transmission wheel is connected with the second machine tool plate; the seventh driving wheel is connected with the rotating track disc.

5. The fat powder extraction processing device of claim 4, wherein: the stirring control mechanism comprises a bearing sleeve column, an eighth driving wheel, a stirring block, an electric stirring plate, an engaging self-rotating sleeve and a screw rod; the bearing sleeve column is inserted with the eighth transmission wheel through a bearing; the eighth driving wheel is connected with the shifting block; the shifting block is in transmission connection with the electric shifting plate; the eighth transmission wheel is rotationally connected with the meshing self-rotating sleeve; the inner side of the meshing self-rotating sleeve is meshed with the screw; the screw rod is connected with the elastic telescopic rod; the electric toggle plate is connected with the third connecting frame; the bearing sleeve column is connected with the reaction cabin; the eighth driving wheel is connected with the third driving wheel.

6. The fat powder extraction processing device of claim 5, wherein: the upper part of the pressing bearing plate is an inclined plane with a lower left part and a higher right part.

7. The fat powder extraction processing device of claim 6, wherein: a stop dog is arranged on the left side of the top end of the pressing bearing plate.

8. The fat powder extraction processing device of claim 7, wherein: a groove is arranged in the middle of the bottom end in the reaction cabin, and the bottom of the solution spray head is contacted with the bottom of the groove.

9. The fat powder extraction processing device of claim 8, wherein: and a transparent observation window is arranged at the bottom of the right end of the reaction cabin.