CN118086042B

CN118086042B - Collagen functional peptide extraction system

Info

Publication number: CN118086042B
Application number: CN202410498137.8A
Authority: CN
Inventors: 赵旭升; 王松茂; 戴震媛; 彭钰涵; 赵珂; 王璐; 马莉莉
Original assignee: Shuimu Xingchen Biopharmaceutical Shenzhen Co ltd
Current assignee: Shuimu Xingchen Biopharmaceutical Shenzhen Co ltd
Priority date: 2024-04-24
Filing date: 2024-04-24
Publication date: 2024-06-28
Anticipated expiration: 2044-04-24
Also published as: CN118086042A

Abstract

The invention discloses a collagen functional peptide extraction system, which relates to the technical field of collagen extraction and comprises a primary enzymolysis tank, wherein the lower end of the primary enzymolysis tank is communicated with a grinding tank, the bottom of the grinding tank is communicated with a storage tank, and the bottom of the storage tank is fixedly connected with a perforated support plate through four support rods; the left sides of the upper surfaces of the perforated support plate and the primary enzymolysis tank are provided with feeding mechanisms; according to the invention, through the feeding mechanism, the speed reducing motor is controlled to start, the speed reducing motor can drive the guide auger sheets to rotate simultaneously, the guide auger sheets can drive raw materials to be upwards transmitted after rotating, then the raw materials can be transmitted into the primary enzymolysis tank through the discharging cylinder, so that automatic feeding of the raw materials is completed, the rotating speed of the guide auger sheets can be controlled through controlling the rotating speed of the speed reducing motor in the feeding mode, so that the raw materials can be driven to be transmitted at a constant speed, and meanwhile, the low-level raw material transmission is time-saving and labor-saving, and the carrying danger is not easy to occur.

Description

Collagen functional peptide extraction system

Technical Field

The invention relates to the technical field of collagen extraction, in particular to a collagen functional peptide extraction system.

Background

The collagen peptide is a product which is produced by taking fresh animal tissues (including skin, bones, tendons, scales and the like) rich in collagen as raw materials, extracting, hydrolyzing and refining and has the relative molecular mass of less than 10000 Da.

The existing collagen peptide extraction system needs to undergo enzymolysis treatment twice, wherein primary enzymolysis is to carry out primary enzymolysis on raw materials, the secondary enzymolysis needs to crush the raw materials subjected to enzymolysis to enter the process of secondary enzymolysis, the existing crushing equipment and the enzymolysis equipment belong to independent equipment, the raw materials need to be put into the crushing equipment for treatment by manpower, the raw materials are taken out from the crushing equipment and transferred into the enzymolysis equipment for secondary enzymolysis treatment, the back and forth transfer easily causes the reduction of the working efficiency of collagen peptide extraction, and the extraction speed is reduced; such as the patent of the patent number cn202310264540.X, in which the transmission of the raw material is completed by pulling the baffle plate by the electric push rod to open the material storage port, this transmission mode requires that the user firstly lifts the raw material manually and transmits the raw material to the inside of the containing device, thus still increasing the manpower, and in which the extraction work of the collagen peptide is realized by the self-priming pump, the motor i, the motor ii, the electric push rod and the motor iii, wherein the extraction efficiency is reduced and then the cost of the extraction equipment is increased and the power consumption of the whole extraction equipment is improved due to the fact that the extraction step of the raw material is increased by the excessive electric appliances.

Disclosure of Invention

In order to solve the defects in the prior art, the invention provides a collagen functional peptide extraction system.

In order to solve the technical problems, the invention provides the following technical scheme:

the invention relates to a collagen functional peptide extraction system, which comprises a primary enzymolysis tank, wherein the lower end of the primary enzymolysis tank is communicated with a grinding tank, the bottom of the grinding tank is communicated with a storage tank, and the bottom of the storage tank is fixedly connected with a support plate with holes through four support rods;

the novel collagen peptide enzymolysis device is characterized in that the left sides of the upper surfaces of the perforated support plate and the primary enzymolysis tank are provided with feeding mechanisms, the primary enzymolysis mechanism for carrying out primary enzymolysis on raw materials is arranged in the primary enzymolysis tank, the dual enzymolysis mechanism for carrying out grinding and dual enzymolysis on the raw materials is arranged in the grinding tank, and the right side surface of the lower end of the storage tank is communicated with a discharging conveying pipe for conveying collagen peptide.

As a preferable technical scheme of the invention, the feeding mechanism comprises a vertical conveying cylinder, the left side of the upper surface of the perforated support plate is fixedly connected with the vertical conveying cylinder, the right side surface of the upper end of the vertical conveying cylinder is communicated with the left side of the upper surface of the primary enzymolysis tank through a discharge cylinder, the middle parts of the upper and lower surfaces of the vertical conveying cylinder are respectively and rotatably connected with a driven vertical shaft through a bearing, the outer wall of the middle section of the driven vertical shaft is fixedly sleeved with a guide auger sheet, the right side of the upper surface of the primary enzymolysis tank is provided with a speed reducing motor, the upper end of the speed reducing motor and the upper end of the driven vertical shaft are respectively and fixedly connected with an upper groove wheel, and driven toothed belts are respectively clamped in grooves of the upper groove wheel.

As a preferable technical scheme of the invention, the primary enzymolysis mechanism comprises an upper filter tank, the inner wall of the middle part of the primary enzymolysis tank is fixedly connected with the upper filter tank, the middle parts of the upper surfaces of the primary enzymolysis tank and the upper filter tank are respectively and rotatably connected with a driven vertical pipe through a bearing, the outer wall of the upper end of the driven vertical pipe is fixedly sleeved with an upper driven gear, the outer wall of an output shaft of the upper end of a gear motor is fixedly sleeved with an upper driving gear, and an upper mixing plate is arranged on the outer wall curve array of the middle section of the driven vertical pipe.

As a preferable technical scheme of the invention, the outer wall of the middle protruding structure of the upper filter tank is fixedly connected with a lower fluted disc, the outer walls of two sides of the middle section of the driven vertical pipe are fixedly connected with driven carriers, the lower ends of the driven carriers are fixedly connected with turning plates on the opposite sides, the two side surfaces of the lower ends of the driven carriers are rotatably connected with driven cross bars through bearings, the outer walls of the opposite ends of the driven cross bars are fixedly sleeved with auxiliary gears, and the outer walls of the driven cross bars are fixedly connected with scattering blocks.

As a preferable technical scheme of the invention, an electric push rod I is fixedly arranged on the right outer wall of the lower end of the primary enzymolysis tank, an auxiliary sieve plate is fixedly connected with the left end of the electric push rod I, material removing scrapers are fixedly connected with the outer walls of the two sides of the lower end of the driven vertical pipe, a main vertical rod is inserted into the inner cavity of the driven vertical pipe, an electric push rod II is fixedly arranged on the left side of the upper surface of the primary enzymolysis tank, the right side of the upper end of the electric push rod II is fixedly sleeved on the outer wall of the upper end of the main vertical rod through a bearing, an upper baffle cover is fixedly sleeved on the inner part of the lower end of the primary enzymolysis tank and positioned on the outer wall of the main vertical rod, and a downloading blade is fixedly sleeved on the outer wall of the upper baffle cover and positioned below the main vertical rod.

As a preferable technical scheme of the invention, the double enzymolysis mechanism comprises a grinding groove, wherein the inner wall of the upper end of the grinding tank is fixedly connected with the grinding groove, the inner walls of the two sides of the upper end of the grinding tank are fixedly connected with bearing brackets, the inner wall of the left side of the lower end of the grinding tank is fixedly connected with two bearing matching plates, the bearing brackets and the right end of the bearing matching plate above are respectively connected with a carrying pipe I through bearings in a rotating way, the inner part of the right end of the bearing matching plate below is connected with a carrying pipe II in a rotating way, and the inner cavity of the carrying pipe II is clamped outside the lower end of a main vertical rod.

As a preferable technical scheme of the invention, the outer part of the upper end of the carrying pipe is fixedly sleeved with the grinding cone disc, the lower mixing blade is fixedly connected to the lower part of the grinding cone disc and positioned on the outer wall of the first carrying pipe, two assembly clamping grooves are formed in the right side surface of the lower end of the grinding tank, double filter plates are clamped in the two assembly clamping grooves, and clamping bolts are connected to the right side surfaces of the double filter plates and the right side surface of the grinding tank in a threaded manner.

As a preferable technical scheme of the invention, two lower conveying hoppers are fixedly connected to the inner wall of the grinding tank below the double filter plates, lower auxiliary covers are fixedly sleeved on the outer walls of the main vertical rods at the outlets of the bottoms of the two lower conveying hoppers, the left side surfaces of the lower ends of the primary enzymolysis tank and the grinding tank are communicated through a feed liquid conveying pipe, and an electromagnetic valve is arranged outside the lower end of the feed liquid conveying pipe.

As a preferable technical scheme of the invention, the upper surface of the front end of the primary enzymolysis tank is communicated with a pipeline for conveying enzymolysis liquid, and the middle part of the front surface of the grinding tank is communicated with a pipeline for conveying enzymolysis liquid.

The beneficial effects of the invention are as follows:

1. This kind of collagen functional peptide extraction system, through the pan feeding mechanism that sets up, at first control gear motor starts, gear motor starts just can drive upper position sheave and driven toothed belt and rotate simultaneously, driven toothed belt rotates just can drive driven vertical axis and guide auger piece and rotate simultaneously, guide auger piece rotates just can drive the raw materials and upwards transmit, then the inside of just can carrying the raw materials to the enzymolysis tank just, the automatic feeding of raw materials has just been accomplished, and this kind of material loading mode can control the rotational speed of guide auger piece through the rotational speed of control gear motor, just so can impel the raw materials to realize at the uniform velocity transmission, simultaneously, low-order raw materials transmission labour saving and time saving, difficult transport danger appears.

2. This kind of collagen functional peptide extraction system, through the primary enzymolysis mechanism that sets up, first electricity push rod starts and can drive supplementary sieve right movement, supplementary sieve right movement just can make its and the filtration pore formation dislocation of upper filter tank bottom, just so make supplementary sieve possess filterable function, then control gear motor starts, gear motor starts just can drive driven standpipe and home position montant and rotate simultaneously, driven standpipe rotates just can drive the removal scraper blade and rotates, the removal scraper blade rotates just can promote the raw materials of bottom and rotate, driven carrier rotates and can also drive the piece of breaking up and spin, just can break up and turn the raw materials of rotation through the rotation of breaking up the piece, just so can improve the enzymolysis efficiency of raw materials, through supplementary sieve, upper hybrid board, the cooperation of removing the piece of scraping and breaking up the piece can effectively accomplish the solid-liquid separation of enzymolysis raw materials, last electricity push rod one, solenoid valve and second cooperation can be with the space of once enzymolysis liquid transmission to the grinding jar bottom, still can be with the automatic transmission of solid raw materials to the space at the grinding jar top, automatic transmission to a great extent of solid raw materials and enzymolysis liquid have been accomplished, the dynamics has reduced the user.

3. This kind of collagen functional peptide extraction system, through the dual enzymolysis mechanism who sets up, first gear motor starts just can drive host computer montant and carrier tube and rotate simultaneously, carrier tube rotation just can drive grinding awl dish rotation, grinding awl dish rotation just can smash and grind the solid raw materials that falls, the raw materials after grinding can carry out secondary enzymolysis in the dual filter plate position of top, lower mixed leaf can accompany carrier tube simultaneous rotation, just so can accelerate the enzymolysis efficiency of raw materials, then control electric putter second start, electric putter second start just can control the lower follow lid and upwards move, lower follow lid upwards move just can impel the lower defeated fill to carry secondary collagen peptide enzymolysis liquid to the bottom space of grinding jar, finally through the lower mixed leaf of below just can accomplish twice enzymolysis liquid and carry out intensive mixing, the hypermembrane filtration of enzymolysis liquid is realized by the double filter plate of below again, just so accomplished the extraction of collagen peptide solution fast, and grinding and enzymolysis liquid's preparation and fusion are accomplished through same equipment, to a great extent has improved the processing efficiency of equipment, and processing cost has also reduced to a great extent.

4. According to the collagen functional peptide extraction system, through the cooperation of the gear motor, the first electric push rod and the second electric push rod, firstly, the complex processing and extraction of raw materials can be realized through fewer electric parts, then the power consumption of extraction equipment is reduced, and the practicability of the extraction equipment is improved to a great extent.

Drawings

The accompanying drawings are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate the invention and together with the embodiments of the invention, serve to explain the invention. In the drawings:

FIG. 1 is a schematic diagram of the structure of the present invention;

FIG. 2 is a top view of the present invention;

FIG. 3 is a right side view of the present invention;

FIG. 4 is a cross-sectional view at a-a in FIG. 2 of the present invention;

FIG. 5 is a partial structure separation diagram of the present invention;

FIG. 6 is a schematic diagram of the connection structure of the primary enzymolysis mechanism and the double enzymolysis mechanism of the invention;

FIG. 7 is a diagram showing the misalignment of the upper filter tank and auxiliary screen plate of the present invention;

FIG. 8 is a bottom view of FIG. 7 in accordance with the present invention;

FIG. 9 is a schematic view of a part of the structure of the primary enzymolysis mechanism of the invention;

Fig. 10 is a schematic view of the connection structure of the main vertical rod, the upper shield cover, the lower transfer blade and the lower slave cover of the present invention.

In the figure: 1. a primary enzymolysis tank; 2. a grinding tank; 3. a storage tank; 4. a support plate with holes; 5. a feeding mechanism; 501. a vertical conveying cylinder; 502. a discharge cylinder; 503. a driven vertical shaft; 504. a guide auger sheet; 505. a speed reducing motor; 506. an upper grooved pulley; 507. a driven toothed belt; 6. a primary enzymolysis mechanism; 601. an upper filter tank; 602. a driven standpipe; 603. an upper slave gear; 604. an upper drive gear; 605. an upper mixing plate; 606. a lower fluted disc; 607. a slave carrier; 608. a turning plate; 609. a driven cross bar; 610. an auxiliary gear; 611. scattering blocks; 612. an electric push rod I; 613. an auxiliary screen plate; 614. a material removing scraper; 615. a main position vertical rod; 616. an electric push rod II; 617. an upper gear cover; 618. downloading the blade; 7. a double enzymolysis mechanism; 701. grinding the groove; 702. a bearing bracket; 703. bearing assembly plates; 704. a first carrying pipe; 705. a second carrying pipe; 706. grinding the conical disc; 707. lower mixed leaves; 708. assembling a clamping groove; 709. a double filter plate; 710. a latch; 711. a lower conveying hopper; 712. a lower slave cover; 713. a feed liquid conveying pipe; 714. an electromagnetic valve; 8. and (5) discharging and conveying the materials.

Detailed Description

The preferred embodiments of the present invention will be described below with reference to the accompanying drawings, it being understood that the preferred embodiments described herein are for illustration and explanation of the present invention only, and are not intended to limit the present invention.

Examples: as shown in fig. 1-10, the collagen functional peptide extraction system comprises a primary enzymolysis tank 1, wherein the lower end of the primary enzymolysis tank 1 is communicated with a grinding tank 2, the bottom of the grinding tank 2 is communicated with a storage tank 3, and the bottom of the storage tank 3 is fixedly connected with a support plate 4 with holes through four support rods; the feeding mechanism 5 is all installed in the left side of foraminiferous extension board 4 and the upper surface of just enzymolysis tank 1, and just the internally mounted of enzymolysis tank 1 has the just enzymolysis mechanism 6 that is used for carrying out enzymolysis once to the raw materials, and the internally mounted of grinding tank 2 has the dual enzymolysis mechanism 7 that is used for grinding and dual enzymolysis to the raw materials, and the right flank intercommunication of storage tank 3 lower extreme has the ejection of compact conveyer pipe 8 that is used for transmitting collagen peptide.

As shown in fig. 3, fig. 4 and fig. 5, the feeding mechanism 5 comprises a vertical conveying cylinder 501, the left side of the upper surface of the perforated support plate 4 is fixedly connected with the vertical conveying cylinder 501, the right side surface of the upper end of the vertical conveying cylinder 501 and the left side of the upper surface of the primary enzymolysis tank 1 are communicated through a discharge cylinder 502, the middle parts of the upper surface and the lower surface of the vertical conveying cylinder 501 are rotationally connected with a driven vertical shaft 503 through bearings, the outer wall of the middle section of the driven vertical shaft 503 is fixedly sleeved with a guide auger sheet 504, the right side of the upper surface of the primary enzymolysis tank 1 is provided with a speed reducing motor 505, the speed reducing motor 505 and the upper end of the driven vertical shaft 503 are fixedly connected with an upper groove wheel 506, and driven toothed belts 507 are clamped in grooves of the upper groove wheel 506.

Wherein, through the pan feeding mechanism 5 that sets up, first control electric putter 612 starts, first electric putter 612 starts and can drive auxiliary screen 613 and remove right, auxiliary screen 613 removes right and just can make its and the filtration pore formation dislocation of upper filter tank 601 bottom, just so make auxiliary screen 613 possess filterable function, then control gear motor 505 starts, gear motor 505 starts just can drive upper sheave 506 and driven toothed belt 507 and rotate simultaneously, driven toothed belt 507 rotates just can drive driven vertical shaft 503 and guide auger piece 504 and rotates simultaneously, guide auger piece 504 rotates just can drive the raw materials and upwards transmit, then discharge cylinder 502 just can transmit the inside of primary enzymolysis tank 1, so just so accomplish the automatic feeding of raw materials, and this kind of material loading mode can be through the rotational speed of control guide auger piece 504 of control gear motor 505, so just can make the raw materials realize at the uniform velocity transmission, simultaneously, low-order raw materials transmission labour saving and time saving, handling danger is difficult for appearing.

As shown in fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9 and fig. 10, the primary enzymolysis mechanism 6 comprises an upper filter tank 601, the inner wall of the middle part of the primary enzymolysis tank 1 is fixedly connected with the upper filter tank 601, the middle parts of the upper surfaces of the primary enzymolysis tank 1 and the upper filter tank 601 are respectively connected with a driven vertical pipe 602 through bearings in a rotating way, the outer wall of the upper end of the driven vertical pipe 602 is fixedly sleeved with an upper driven gear 603, the outer wall of an output shaft of the upper end of the gear motor 505 is fixedly sleeved with an upper driving gear 604, and an upper mixing plate 605 is arranged on the curve array of the outer wall of the middle section of the driven vertical pipe 602; the outer wall of the middle protruding structure of the upper filter tank 601 is fixedly connected with a lower fluted disc 606, the outer walls of two sides of the middle section of the driven vertical tube 602 are fixedly connected with driven carriers 607, the lower ends of the driven carriers 607 are fixedly connected with turning plates 608 on the opposite sides, two side surfaces of the lower ends of the driven carriers 607 are rotatably connected with driven cross rods 609 through bearings, the outer walls of the opposite ends of the driven cross rods 609 are fixedly sleeved with auxiliary gears 610, and the outer walls of the driven cross rods 609 are fixedly connected with scattering blocks 611; the right side outer wall fixed mounting of just enzymolysis tank 1 lower extreme has electric push rod one 612, the left end fixedly connected with auxiliary screen board 613 of electric push rod one 612, the equal fixedly connected with of both sides outer wall of driven standpipe 602 lower extreme removes material scraper blade 614, the inner chamber grafting of driven standpipe 602 has host site montant 615, the left side fixed mounting of just enzymolysis tank 1 upper surface has electric push rod two 616, and the right side of electric push rod two 616 upper end is fixed cup joint in the outer wall of host site montant 615 upper end through the bearing, the inside of just enzymolysis tank 1 lower extreme and the fixed cup joint of outer wall that is located host site montant 615 have put up the fender lid 617, the below that put fender lid 617 and the fixed cup joint of outer wall that is located host site montant 615 have down the blade 618.

Wherein, through the cooperation of the primary enzymolysis mechanism 6 and the double enzymolysis mechanism 7, firstly, the enzymolysis agent is transmitted to the inside of the primary enzymolysis tank 1 through a pipeline arranged above, then the speed reducing motor 505 is controlled to start, the speed reducing motor 505 is started to drive the upper driving gear 604 to rotate, the upper driving gear 604 can drive the upper driven gear 603 and the driven vertical pipe 602 to rotate simultaneously, the driven vertical pipe 602 and the main vertical pipe 615 rotate simultaneously, the driven vertical pipe 602 can drive the upper mixing plate 605 and the driven carrier 607 to rotate simultaneously, the upper mixing plate 605 can drive the raw materials and the enzymolysis agent to realize primary mixing, the driven carrier 607 can drive the material removing scraping plate 614 to rotate, the material removing scraping plate 614 can drive the raw materials at the bottom to rotate, the driven carrier 607 can also drive the auxiliary gear to rotate on the lower fluted disc 606, the auxiliary gear 610 rotates to drive the driven cross rod 609 and the scattering block 611 to rotate simultaneously, the rotating raw materials can be scattered and turned through the rotation of the scattering block 611, so that the enzymolysis efficiency of the raw materials can be improved, the solid-liquid separation of the enzymolysis raw materials can be effectively completed through the cooperation of the auxiliary screen plate 613, the upper mixing plate 605, the material removing scraping plate 614 and the scattering block 611, the electromagnetic valve 714 is controlled to be opened, the material liquid conveying pipe 713 can firstly convey primary collagen peptide enzymolysis liquid to the space at the bottom of the grinding tank 2, then the electric push rod 612 is controlled to be started, the electric push rod 612 can drive the auxiliary screen plate 613 to return to the initial position leftwards, the auxiliary screen plate 613 can downwards convey the separated solid raw materials to the bottom space of the primary enzymolysis tank 1, finally the electric push rod 616 is controlled to be started, the electric push rod 616 can drive the main vertical rod 615 and the upper blocking cover 617 to move upwards simultaneously, thus, the opening of the outlet at the bottom of the primary enzymolysis tank 1 is completed, and the automatic transmission of the solid raw materials is completed by the convenient downloading blade 618, so that the labor intensity of a user is reduced to a great extent.

As shown in fig. 3, fig. 4, fig. 5, fig. 6 and fig. 10, the double enzymolysis mechanism 7 comprises a grinding groove 701, the inner wall of the upper end of the grinding tank 2 is fixedly connected with the grinding groove 701, the inner walls of the two sides of the upper end of the grinding tank 2 are fixedly connected with a bearing bracket 702, the inner wall of the left side of the lower end of the grinding tank 2 is fixedly connected with two bearing matching plates 703, the right ends of the bearing bracket 702 and the upper bearing matching plates 703 are respectively connected with a first carrying tube 704 through bearings in a rotating manner, the inner part of the right end of the lower bearing matching plate 703 is rotatably connected with a second carrying tube 705, and the inner cavity of the second carrying tube 705 is clamped outside the lower end of the main vertical rod 615; the outer part of the upper end of the first carrying pipe 704 is fixedly sleeved with a grinding cone disc 706, the lower part of the grinding cone disc 706 is fixedly connected with a lower mixing blade 707 on the outer wall of the first carrying pipe 704, the right side surface of the lower end of the grinding tank 2 is provided with two assembly clamping grooves 708, the inner parts of the two assembly clamping grooves 708 are respectively clamped with a double filter plate 709, and the right side surfaces of the double filter plates 709 and the right side surface of the grinding tank 2 are respectively in threaded connection with a clamping bolt 710; the inner wall fixedly connected with two lower position defeated fill 711 of dual filter plate 709 below and being located grinding jar 2, the exit of two lower position defeated fill 711 bottoms and the outer wall that is located main position montant 615 all fixedly cup joint lower position follow lid 712, and the left surface of just enzymolysis tank 1 and grinding jar 2 lower extreme all communicates through feed liquid conveying pipe 713, and the externally mounted of feed liquid conveying pipe 713 lower extreme has the solenoid valve.

Wherein, through the cooperation of double enzymolysis mechanism 7 and just enzymolysis mechanism 6, first control electric putter two 616 starts, electric putter two 616 starts just can control two lower follow lid 712 and upwards move simultaneously, two lower follow lid 712 upwards move just can control respectively that the lower of top is defeated fill 711 and lower of below is defeated fill 711 is closed, the lower of opening is defeated fill 711 can be transmitted the bottom space of grinding jar 2 with the collagen peptide enzymolysis liquid, so the collagen peptide enzymolysis liquid of secondary just can fuse together with primary collagen peptide enzymolysis liquid, the rethread below lower mixed leaf 707 just can accomplish twice enzymolysis liquid and carry out intensive mixing, the milipore filter of enzymolysis liquid is realized by the double filter plate 709 of below again, so just accomplish the extraction of collagen peptide solution fast, finally control electric putter two starts, electric putter two 616 starts just can drive lower follow lid 712 and move down, just so can make the lower of below defeated fill 711 realize opening, the lower of lower is defeated fill can be opened the bottom and just can be had the collagen peptide liquid to take out fill with the filter plate 710 to the filter plate 8, the filter plate 8 is so the filter plate that the filter plate is carried out to the realization is carried out to the filter plate 8 when the filter plate that the filter plate is opened, the filter plate is convenient for the whole, the filter plate 8 is so the filter plate is realized to the filter plate is opened, the filter plate is convenient for the whole and can be replaced to the filter plate 8, the filter plate is convenient for the surface-to install and has been replaced to the drain the collagen peptide is more, and can be used to the filter plate 8.

The upper surface of the front end of the primary enzymolysis tank 1 is communicated with a pipeline for conveying enzymolysis liquid, and the middle part of the front surface of the grinding tank 2 is communicated with a pipeline for conveying enzymolysis liquid.

Wherein, can conveniently transmit enzymolysis agent respectively to the inside of just enzymolysis tank 1 and grinding jar 2 through the pipeline that sets up.

During operation, firstly, raw materials are conveyed: firstly, the first electric push rod 612 is controlled to start, the first electric push rod 612 can drive the auxiliary screen plate 613 to move rightwards, the auxiliary screen plate 613 can be caused to form dislocation with the filter holes at the bottom of the upper filter tank 601 by moving rightwards, the auxiliary screen plate 613 is caused to have a filtering function, then the speed reducing motor 505 is controlled to start, the speed reducing motor 505 can drive the upper grooved wheel 506 and the driven toothed belt 507 to rotate simultaneously, the driven toothed belt 507 can drive the driven vertical shaft 503 and the guide auger sheet 504 to rotate simultaneously, the guide auger sheet 504 can rotate to drive raw materials to be transmitted upwards, then the discharge cylinder 502 can transmit the raw materials into the primary enzymolysis tank 1, automatic feeding of the raw materials is completed, and the feeding mode can control the rotating speed of the guide auger sheet 504 by controlling the rotating speed of the speed reducing motor 505, so that the raw materials can be caused to realize uniform speed transmission;

Then carrying out primary enzymolysis: firstly, the enzymolysis agent is transmitted into the primary enzymolysis tank 1 through a pipeline arranged above, then the speed reducing motor 505 is controlled to start, the speed reducing motor 505 can drive the upper driving gear 604 to rotate, the upper driving gear 604 can drive the upper driven gear 603 and the driven vertical pipe 602 to rotate simultaneously, the driven vertical pipe 602 and the main vertical pipe 615 rotate simultaneously, the driven vertical pipe 602 can drive the upper mixing plate 605 and the driven carrier 607 to rotate simultaneously, the rotation of the upper mixing plate 605 can drive the raw materials and the enzymolysis agent to realize primary mixing, the rotation of the driven carrier 607 can drive the material removing scraping plate 614 to rotate, the rotation of the material removing scraping plate 614 can drive the raw materials at the bottom to rotate, the rotation of the driven carrier 607 can also drive the auxiliary gear to rotate on the lower fluted disc 606, the rotation of the auxiliary gear 610 can drive the driven cross rod 609 and the breaking block 611 to rotate simultaneously, the rotating raw materials can be scattered and turned over by the rotation of the scattering block 611, so that the enzymolysis efficiency of the raw materials can be improved, the solid-liquid separation of the enzymolysis raw materials can be effectively completed by the cooperation of the auxiliary screen plate 613, the upper mixing plate 605, the material removing scraping plate 614 and the scattering block 611, the electromagnetic valve 714 is controlled to be opened, the primary collagen peptide enzymolysis liquid can be firstly transmitted to the space at the bottom of the grinding tank 2 by the feed liquid conveying pipe 713, then the electric push rod one 612 is controlled to be started, the auxiliary screen plate 613 can be driven to return to the initial position leftwards by the starting of the electric push rod one 612, the separated solid raw materials can be downwards transmitted to the bottom space of the primary enzymolysis tank 1 by the auxiliary screen plate 613, finally the electric push rod two 616 is controlled to be started, the main vertical rod 615 and the upper baffle cap 617 can be driven to move upwards simultaneously, so that the opening of the outlet at the bottom of the primary enzymolysis tank 1 is completed, thereby facilitating the automatic transfer of solid materials by the transfer blade 618;

grinding the raw materials: firstly, a gear motor 505 is started to drive a main vertical rod 615 and a first carrying pipe 704 to rotate simultaneously, the first carrying pipe 704 rotates to drive a grinding cone disc 706 to rotate, and the grinding cone disc 706 rotates to crush and grind solid raw materials in a grinding groove 701;

And then carrying out secondary enzymolysis: firstly, an enzymolysis agent is conveyed to the middle position of an inner cavity of a grinding tank 2 through a pipeline arranged on the grinding tank 2, then a main vertical rod 615 and a lower mixed blade 707 are controlled to rotate through a speed reducing motor 505, the lower mixed blade 707 can drive the enzymolysis agent to rapidly carry out enzymolysis on raw materials, secondary collagen peptide enzymolysis liquid is further rapidly prepared, and the secondary collagen peptide enzymolysis liquid can be filtered through a double filter plate 709 above and is conveyed into a lower conveying hopper 711 above;

Finally, mixing the enzymolysis liquid twice: firstly, the electric push rod II 616 is controlled to start, the electric push rod II 616 can control the two lower side slave covers 712 to move upwards at the same time, the two lower side slave covers 712 can respectively control the upper lower side delivery hopper 711 to open and the lower side delivery hopper 711 to close, the opened lower side delivery hopper 711 can transmit the secondary collagen peptide enzymatic hydrolysate to the bottom space of the grinding tank 2, the secondary collagen peptide enzymatic hydrolysate can be fused with the primary collagen peptide enzymatic hydrolysate, the two enzymatic hydrolysate can be fully mixed rapidly through the lower side mixed leaves 707 at the lower side, the ultrafiltration membrane filtration of the enzymatic hydrolysate is realized through the double filter plates 709 at the lower side, thus the extraction of the collagen peptide solution is completed rapidly, finally, the electric push rod II 616 is controlled to start again, the lower side delivery hopper 711 can be driven to move downwards through the cover 712, the lower side delivery hopper 711 can be opened, the extracted collagen peptide liquid can be transmitted to the inside the storage tank 3, the collagen peptide liquid can be collected and the collagen peptide liquid can be discharged from the discharge pipe 8 through the storage tank 3, and the collagen peptide delivery pipe 8 can be arranged.

Finally, it should be noted that: the foregoing description is only a preferred embodiment of the present invention, and the present invention is not limited thereto, but it is to be understood that modifications and equivalents of some of the technical features described in the foregoing embodiments may be made by those skilled in the art, although the present invention has been described in detail with reference to the foregoing embodiments. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims

1. The collagen functional peptide extraction system comprises a primary enzymolysis tank (1), and is characterized in that the lower end of the primary enzymolysis tank (1) is communicated with a grinding tank (2), the bottom of the grinding tank (2) is communicated with a storage tank (3), and the bottom of the storage tank (3) is fixedly connected with a support plate (4) with holes through four support rods;

The novel collagen peptide enzymolysis device is characterized in that the left sides of the upper surfaces of the perforated support plate (4) and the primary enzymolysis tank (1) are respectively provided with a feeding mechanism (5), the interior of the primary enzymolysis tank (1) is provided with a primary enzymolysis mechanism (6) for carrying out primary enzymolysis on raw materials, the interior of the grinding tank (2) is provided with a double enzymolysis mechanism (7) for grinding and double enzymolysis on the raw materials, and the right side surface of the lower end of the storage tank (3) is communicated with a discharging conveying pipe (8) for conveying collagen peptide;

The feeding mechanism (5) comprises a vertical conveying cylinder (501), the left side of the upper surface of a perforated support plate (4) is fixedly connected with the vertical conveying cylinder (501), the right side surface of the upper end of the vertical conveying cylinder (501) is communicated with the left side of the upper surface of a primary enzymolysis tank (1) through a discharge cylinder (502), the middle parts of the upper surface and the lower surface of the vertical conveying cylinder (501) are respectively connected with a driven vertical shaft (503) through bearing rotation, the outer wall of the middle section of the driven vertical shaft (503) is fixedly sleeved with a guide auger sheet (504), the right side of the upper surface of the primary enzymolysis tank (1) is provided with a gear motor (505), the upper end of the gear motor (505) and the upper end of the driven vertical shaft (503) are respectively fixedly connected with an upper grooved pulley (506), and driven toothed belts (507) are respectively clamped in grooves of the upper grooved pulley (506);

The primary enzymolysis mechanism (6) comprises an upper filter tank (601), the inner wall of the middle part of the primary enzymolysis tank (1) is fixedly connected with the upper filter tank (601), the middle parts of the upper surfaces of the primary enzymolysis tank (1) and the upper filter tank (601) are respectively connected with a driven vertical pipe (602) through bearing rotation, the outer wall of the upper end of the driven vertical pipe (602) is fixedly sleeved with an upper driven gear (603), the outer wall of the output shaft of the upper end of the gear motor (505) is fixedly sleeved with an upper driving gear (604), and an upper mixing plate (605) is arranged on the outer wall curve array of the middle section of the driven vertical pipe (602);

the outer wall of the middle part protruding structure of the upper filter tank (601) is fixedly connected with a lower fluted disc (606), the outer walls of two sides of the middle section of the driven vertical tube (602) are fixedly connected with driven carriers (607), the lower ends of the driven carriers (607) are fixedly connected with turning plates (608) on the opposite sides, the two side surfaces of the lower ends of the driven carriers (607) are respectively connected with driven cross rods (609) through bearings in a rotating mode, the outer walls of the opposite ends of the driven cross rods (609) are respectively fixedly sleeved with an auxiliary gear (610), and the outer walls of the driven cross rods (609) are respectively fixedly connected with scattering blocks (611);

The right side outer wall of the lower end of the primary enzymolysis tank (1) is fixedly provided with an electric push rod I (612), the left end of the electric push rod I (612) is fixedly connected with an auxiliary sieve plate (613), the outer walls of the two sides of the lower end of the driven vertical pipe (602) are fixedly connected with a material removing scraping plate (614), the inner cavity of the driven vertical pipe (602) is inserted with a main position vertical rod (615), the left side of the upper surface of the primary enzymolysis tank (1) is fixedly provided with an electric push rod II (616), the right side of the upper end of the electric push rod II (616) is fixedly sleeved on the outer wall of the upper end of the main position vertical rod (615) through a bearing, the inner part of the lower end of the primary enzymolysis tank (1) is fixedly sleeved with an upper position blocking cover (617), and the outer wall of the upper position blocking cover (617) is fixedly sleeved with a lower transmission blade (618).

The double enzymolysis mechanism (7) comprises a grinding groove (701), wherein the inner wall of the upper end of the grinding tank (2) is fixedly connected with the grinding groove (701), the inner walls of the two sides of the upper end of the grinding tank (2) are fixedly connected with bearing brackets (702), the inner wall of the left side of the lower end of the grinding tank (2) is fixedly connected with two bearing matching plates (703), the bearing brackets (702) and the right end of the bearing matching plate (703) above are both connected with a first carrier tube (704) through bearings in a rotating manner, the inner part of the right end of the bearing matching plate (703) below is connected with a second carrier tube (705) in a rotating manner, and the inner cavity of the second carrier tube (705) is clamped outside the lower end of a main vertical rod (615);

the outer part of the upper end of the first carrying pipe (704) is fixedly sleeved with a grinding conical disc (706), the lower part of the grinding conical disc (706) is fixedly connected with a lower mixing blade (707) on the outer wall of the first carrying pipe (704), two assembly clamping grooves (708) are formed in the right side surface of the lower end of the grinding tank (2), double filter plates (709) are clamped in the two assembly clamping grooves (708), and clamping bolts (710) are in threaded connection with the right side surface of the double filter plates (709) and the right side surface of the grinding tank (2);

The double filter plate (709) below and be located the inner wall fixedly connected with two lower conveying hoppers (711) of grinding jar (2), two the exit of lower conveying hoppers (711) bottom and be located the outer wall of host post montant (615) all fixedly cup joint lower follow lid (712), the left surface of just enzymolysis tank (1) and grinding jar (2) lower extreme all communicates through feed liquid conveying pipe (713), the externally mounted of feed liquid conveying pipe (713) lower extreme has the solenoid valve.

2. The collagen functional peptide extraction system according to claim 1, wherein the upper surface of the front end of the primary enzymolysis tank (1) is communicated with a pipeline for conveying enzymolysis liquid, and the middle part of the front surface of the grinding tank (2) is communicated with a pipeline for conveying enzymolysis liquid.