阅读说明：本技术 一种活性小分子羊胎素冻干粉生产设备 (Active small molecule sheep placenta freeze-dried powder production facility ) 是由 程红梅 于 2020-07-28 设计创作，主要内容包括：本发明属于农副产品加工设备技术领域,涉及一种活性小分子羊胎素冻干粉生产设备,包括固定机构、清水机构、进料机构、搅碎机构、废水箱、高温搅拌机构、高温酶解机构和过滤机构,所述清水机构、进料机构、搅碎机构、废水箱、高温搅拌机构、高温酶解机构和过滤机构均设置在固定机构上,所述进料机构和清水机构均与搅碎机构连接,所述搅碎机构与废水箱和高温搅拌设备呈上下连接状态,所述高温搅拌机构和高温酶解机构呈上下连接状态,所述高温酶解机构与过滤机构连接。以解决现有技术在提取过程中存在对羊胎素提取时造成羊胎素本体内的营养流水的可能,且在提取完成后无法对设备自动清洗,需要人工清洗,且设备清洗过于麻烦,影响了作业效率为目的。(The invention belongs to the technical field of agricultural and sideline product processing equipment, and relates to active small molecule sheep placenta freeze-dried powder production equipment which comprises a fixing mechanism, a clear water mechanism, a feeding mechanism, a stirring mechanism, a waste water tank, a high-temperature stirring mechanism, a high-temperature enzymolysis mechanism and a filtering mechanism, wherein the clear water mechanism, the feeding mechanism, the stirring mechanism, the waste water tank, the high-temperature stirring mechanism, the high-temperature enzymolysis mechanism and the filtering mechanism are all arranged on the fixing mechanism, the feeding mechanism and the clear water mechanism are all connected with the stirring mechanism, the waste water tank and the high-temperature stirring device are in a vertical connection state, the high-temperature stirring mechanism and the high-temperature enzymolysis mechanism are in a vertical connection state, and the high-temperature enzymolysis mechanism is connected with the filtering mechanism. The method aims to solve the problem that nutrition flowing water in a sheep placenta body is caused when the sheep placenta is extracted in the extraction process in the prior art, and the equipment cannot be automatically cleaned after the extraction is finished, so that the equipment needs to be manually cleaned, and is too troublesome to clean, and the operation efficiency is influenced.)

1. The active small molecule sheep placenta lyophilized powder production equipment is characterized by comprising a fixing mechanism (1), a clear water mechanism (2), a feeding mechanism (5), a stirring mechanism (3), a waste water tank (4), a high-temperature stirring mechanism (6), a high-temperature enzymolysis mechanism (7) and a filtering mechanism (8), wherein the clear water mechanism (2), the feeding mechanism (5), the stirring mechanism (3), the waste water tank (4), the high-temperature stirring mechanism (6), the high-temperature enzymolysis mechanism (7) and the filtering mechanism (8) are all arranged on the fixing mechanism (1), the feeding mechanism (5) and the clear water mechanism (2) are connected with the stirring mechanism (3), the stirring mechanism (3) is in an upper-lower connection state with the waste water tank (4) and the high-temperature stirring mechanism (6), and the high-temperature stirring mechanism (6) and the high-temperature enzymolysis mechanism (7) are in an upper-lower connection state, the high-temperature enzymolysis mechanism (7) is connected with the filtering mechanism (8).

2. The active small molecule ovine placenta freeze-dried powder production equipment according to claim 1, wherein the fixing mechanism (1) comprises a bottom fixing plate (101), a middle fixing plate (102), a top fixing plate (103) and four fixing columns (104), the bottom fixing plate (101), the middle fixing plate (102) and the top fixing plate (103) are correspondingly arranged from top to bottom, the bottom ends of the four fixing columns (104) are respectively arranged at four corners above the bottom fixing plate (101), and the top ends of the four fixing columns (104) penetrate through the middle fixing plate (102) and are arranged at four corners below the top fixing plate (103).

3. The active small molecule ovine placenta freeze-dried powder production equipment according to claim 2, wherein the clear water mechanism (2) comprises a clear water tank (201), a first water pump (202), a water outlet pipe (203) and a connecting pipe (204), the clear water tank (201) is arranged on the top layer fixing plate (103), the first water pump (202) is arranged in the clear water tank (201), one end of the water outlet pipe (203) is connected with the first water pump (202), the other end of the water outlet pipe (203) is connected with one end of the connecting pipe (204), and the other end of the connecting pipe (204) is connected with the mincing mechanism (3).

4. The active small molecule ovine placenta freeze-dried powder production equipment according to claim 3, wherein the mincing mechanism (3) comprises a mincing box (301), a water inlet (302), a first valve (303), a first motor (304), a pulverizing rod (305), a water outlet (306), a second valve (307), a forked pipeline (308), a third valve (309) and a fourth valve (310), the mincing box (301) is arranged on the top layer fixing plate (103) and is positioned at one side of the clear water tank (201), the water outlet (306) is arranged above the mincing box (301), the first valve (303) is arranged in the water inlet (302), the water inlet (302) is connected with a connecting pipe (204), the first motor (304) is arranged above the mincing box (301) and is positioned at one side of the water inlet (302), the output end of the first motor (304) is connected with the pulverizing rod (305), crushing pole (305) set up in stirring case (301), delivery port (306) set up in the bottom of stirring case (301), delivery port (306) run through top layer fixed plate (103) and are connected with branching type pipeline (308), branching type pipeline (308) set up the below at top layer fixed plate (103), the both ends of branching type pipeline (308) are connected with high temperature rabbling mechanism (6) and waste water tank (4) respectively, second valve (307) set up on delivery port (306), third valve (309) and fourth valve (310) all set up on branching type pipeline (308) and are located one side of high temperature rabbling mechanism (6), fourth valve (310) are located one side of waste water tank (4).

5. The active small molecule ovine placenta freeze-dried powder production equipment according to claim 4, wherein the feeding mechanism (5) comprises a feeding box (501), a box cover (502) and a first feeding pipe (503), one end of the first feeding pipe (503) is connected with the mincing box (301), the other end of the first feeding pipe (503) is connected with the feeding box (501), the feeding box (501) is arranged on one side of the mincing box (301), and the box cover (502) is arranged above the feeding box (501).

6. The active small molecule ovine placenta freeze-dried powder production equipment according to claim 4, wherein the high temperature stirring mechanism (6) comprises a first protection box (601), a first heating box (602), an additive feeding hole (603), a first heating wire (604), a first relay (605), a second motor (606), a stirring rod (607), a first discharging pipe (608) and a fifth valve (609), the first protection box (601) is arranged on the middle fixing plate (102) and is positioned at one side of the wastewater box (4), the first heating box (602) is arranged in the first protection box (601), the top of the first heating box (602) is connected with a branched pipeline (308), the first heating wire (604) is arranged around the first heating box (602), the first relay (605) is arranged on the first protection box (601), and the first relay (605) is connected with the first heating wire (604), the additive feed inlet (603) is arranged above the first heating box (602), the top of the additive feed inlet (603) penetrates through the first protective box (601) and the top layer fixing plate (103) and extends out of one end, the second motor (606) is arranged at the bottom of the first heating box (602), the stirring rod (607) is arranged in the first heating box (602), the first discharge pipe (608) is arranged at the bottom of the first heating box (602), and the fifth valve (609) is arranged on the first discharge pipe (608).

7. The active small molecule ovine placenta lyophilized powder production equipment according to claim 2, wherein the high temperature enzymolysis mechanism (7) comprises a second protection box (701), a second heating box (702), a second feeding pipe (703), a sixth valve (704), a second heating wire (705), a second relay (706), a second discharging pipe (707) and a seventh valve (708), the second protection box (701) is arranged on the bottom fixing plate (101), the second heating box (702) is arranged in the second protection box (701), the second feeding pipe (703) is arranged on the top of the second heating box (702), the sixth valve (704) is arranged on the second feeding pipe (703), the second heating wire (705) is arranged around the second heating box (702), the second heating wire (705) is connected with the relay, and the second relay (706) is arranged on the second protection box (701), the second discharge pipe (707) is arranged on one side of the second heating tank (702), and the seventh valve (708) is arranged on the second discharge pipe (707).

8. The active small molecule ovine placenta lyophilized powder production equipment according to claim 7, wherein the filtering mechanism (8) comprises a second water pump (801), a third feeding pipe (802), a filtering box (803), a filtering plate (804), a sealing plate (805), a cylinder (806), a connecting plate (807), a waste water outlet pipe (808)

And an eighth valve (809), the second water pump (801) is arranged on the bottom fixing plate (101) and is located between the filter box (803) and the second protection box (701), two working ends of the second water pump (801) are respectively connected with the second discharge pipe (707) and the third feed pipe (802), the third connecting pipe (204) is connected with the filter box (803), the filter box (803) is arranged on the bottom fixing plate (101), the filter plate (804) is arranged in the filter box (803), the filter box (803) is provided with a rectangular opening hole (8031), the sealing plate (805) is arranged on one side of the rectangular opening hole (8031), the connecting plate (807) is arranged on one side of the sealing plate (805), the air cylinder (806) is arranged at the bottom of the connecting plate (807), the output end of the air cylinder (806) is connected with the connecting plate (807), the wastewater outlet pipe (808) is arranged on one side of the filter box (803) and is located at the bottom of the sealing plate (805) And the eighth valve (809) is arranged on a waste water outlet pipe (808).

Technical Field

The invention relates to the technical field of agricultural and sideline product processing equipment, in particular to equipment for producing active small molecular sheep placenta freeze-dried powder.

Background

The sheep placenta is rich in embryo of sheep mother body after 1-3 months of pregnancy, is a compound of various bioactive substances, and comprises various amino acids, phospholipid, lipopolysaccharide, various vitamins, various trace elements, various immune factors, various multienzyme, humoral regulation factor, growth factor and mysterious substances which are not decoded at present but can effectively stimulate the vitality of human body, namely vitamin X and the like. The sheep placenta extract has good physiological balance regulating effect, can prevent diseases, and is a natural substance capable of promoting health, replenishing blood, invigorating qi, caring skin, maintaining vitality, and improving immunity and disease resistance of human body. Therefore, the sheep placenta extract can be used as a raw material or an additive of medicines, foods, health products and cosmetics.

However, the investment of the existing sheep placenta essence production equipment is large, the extraction process is complex, the extraction process is time-consuming and labor-consuming, and simultaneously, the loss of active ingredients of the sheep placenta essence is large. Therefore, in order to solve the above technical problems, it is necessary to provide an active small molecule ovine placenta lyophilized powder production apparatus with an improved structure to overcome the above-mentioned drawbacks in the prior art

Disclosure of Invention

The invention aims to provide equipment for producing active small-molecule sheep placenta freeze-dried powder, which aims to solve the technical problem in the background technology.

The invention provides active small molecule sheep placenta freeze-dried powder production equipment which comprises a fixing mechanism, a clear water mechanism, a feeding mechanism, a stirring mechanism, a waste water tank, a high-temperature stirring mechanism, a high-temperature enzymolysis mechanism and a filtering mechanism, wherein the clear water mechanism, the feeding mechanism, the stirring mechanism, the waste water tank, the high-temperature stirring mechanism, the high-temperature enzymolysis mechanism and the filtering mechanism are all arranged on the fixing mechanism, the feeding mechanism and the clear water mechanism are all connected with the stirring mechanism, the waste water tank and the high-temperature stirring mechanism are in a vertical connection state, the high-temperature stirring mechanism and the high-temperature enzymolysis mechanism are in a vertical connection state, and the high-temperature enzymolysis mechanism is connected with the filtering mechanism.

Furthermore, the fixing mechanism comprises a bottom fixing plate, a middle fixing plate, a top fixing plate and four fixing columns, wherein the bottom fixing plate, the middle fixing plate and the top fixing plate are arranged in an up-middle-down position, the bottom ends of the four fixing columns are respectively arranged at four corners above the bottom fixing plate, and the top ends of the four fixing columns penetrate through the middle fixing plate and are arranged at four corners below the top fixing plate.

Further, clear water mechanism includes clear water tank, first water pump, outlet pipe and connecting pipe, clear water tank sets up on the top layer fixed plate, first water pump sets up in clear water tank, the one end and the first water pump of outlet pipe are connected, the other end and the one end of connecting pipe of outlet pipe are connected, the other end and the mincing mechanism of connecting pipe are connected.

Further, the stirring mechanism comprises a stirring box, a water inlet, a first valve, a first motor, a crushing rod, a water outlet, a second valve, a forked pipeline, a third valve and a fourth valve, the stirring box is arranged on the top layer fixing plate and located on one side of the clean water tank, the water outlet is arranged above the stirring box, the first valve is arranged in the water inlet, the water inlet is connected with the connecting pipe, the first motor is arranged above the stirring box and located on one side of the water inlet, the output end of the first motor is connected with the crushing rod, the crushing rod is arranged in the stirring box, the water outlet is arranged at the bottom of the stirring box, the water outlet penetrates through the top layer fixing plate and is connected with the forked pipeline, the forked pipeline is arranged below the top layer fixing plate, two ends of the forked pipeline are respectively connected with the high-temperature stirring mechanism and the waste water tank, the second valve is arranged on the water outlet, the third valve and the fourth valve are both arranged on the forked pipeline and located on one side of the high-temperature stirring mechanism, and the fourth valve is located on one side of the waste water tank.

Further, feed mechanism includes feeding case, case lid and first inlet pipe, the one end and the crushing case of first inlet pipe are connected, the other end and the feeding case of first inlet pipe are connected, the feeding case sets up in one side of crushing case, the case lid sets up the top at the feeding case.

Further, the high-temperature stirring mechanism comprises a first protection box, a first heating box, an additive feeding hole, a first heating wire, a first relay, a second motor, a stirring rod, a first discharging pipe and a fifth valve, the first protection box is arranged on the middle layer fixing plate and is positioned on one side of the wastewater box, the first heating box is arranged in the first protection box, the top of the first heating box is connected with a forked pipeline, the first heating wire is arranged around the first heating box, the first relay is arranged on the first protection box, the first relay is connected with the first heating wire, the additive feeding hole is arranged above the first heating box, the upper portion of the additive feeding hole penetrates through the first protection box and the top layer fixing plate and extends out of one end, the second motor is arranged at the bottom of the first heating box, the stirring rod is arranged in the first heating box, the first discharging pipe is arranged at the bottom of the first heating box, and the fifth valve is arranged on the first discharging pipe.

Further, high temperature enzymolysis mechanism includes second protecting box, second heating cabinet, second inlet pipe, sixth valve, second heater strip, second relay, second discharging pipe and seventh valve, the second protecting box sets up on the bottom fixed plate, the second heating cabinet sets up in the second protecting box, the second inlet pipe sets up the top at the second heating cabinet, the sixth valve sets up on the second inlet pipe, the second heater strip sets up around the second heating cabinet, the second heater strip is connected with the relay, the second relay sets up on the second protecting box, the second discharging pipe sets up the one side at the second heating cabinet, the seventh valve sets up on the second discharging pipe.

Furthermore, the filtering mechanism comprises a second water pump, a third feeding pipe, a filtering box, a filtering plate, a sealing plate, a cylinder, a connecting plate, a waste water outlet pipe and an eighth valve, the second water pump is arranged on the bottom fixing plate and positioned between the filtering box and the second protecting box, two working ends of the second water pump are respectively connected with the second discharging pipe and the third feeding pipe, the third connecting pipe is connected with the filtering box, the filtering box is arranged on the bottom fixing plate, the filtering plate is arranged in the filtering box, the filtering box is provided with a rectangular opening hole, the sealing plate is arranged on one side of the rectangular opening hole, the connecting plate is arranged on one side of the sealing plate, the cylinder is arranged at the bottom of the connecting plate, the output end of the cylinder is connected with the connecting plate, the waste water outlet pipe is arranged on one side of the filtering box and positioned at the bottom of the sealing plate, the eighth valve is arranged on the waste water outlet pipe.

Compared with the prior art, the invention has the beneficial effects that:

the invention provides active small molecule sheep placenta freeze-dried powder production equipment which comprises a fixing mechanism, a clear water mechanism, a feeding mechanism, a stirring mechanism, a waste water tank, a high-temperature stirring mechanism, a high-temperature enzymolysis mechanism and a filtering mechanism, wherein the clear water mechanism, the feeding mechanism, the stirring mechanism, the waste water tank, the high-temperature stirring mechanism, the high-temperature enzymolysis mechanism and the filtering mechanism are all arranged on the fixing mechanism, the feeding mechanism and the clear water mechanism are all connected with the stirring mechanism, the waste water tank and the high-temperature stirring device are in a vertical connection state, the high-temperature stirring mechanism and the high-temperature enzymolysis mechanism are in a vertical connection state, and the high-temperature enzymolysis mechanism is connected with the filtering mechanism. The method aims to solve the problem that nutrition flowing water in a sheep placenta body is caused when the sheep placenta is extracted in the extraction process in the prior art, and the equipment cannot be automatically cleaned after the extraction is finished, so that the equipment needs to be manually cleaned, and is too troublesome to clean, and the operation efficiency is influenced.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are some embodiments of the present invention, and other drawings can be obtained by those skilled in the art without creative efforts.

FIG. 1 is a front view of the present invention;

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

FIG. 3 is a cross-sectional view of the present invention;

fig. 4 is a partial structural schematic diagram of the present invention.

Reference numerals: the device comprises a fixing mechanism 1, a bottom layer fixing plate 101, a middle layer fixing plate 102, a top layer fixing plate 103, a fixing column 104, a clean water mechanism 2, a clean water tank 201, a first water pump 202, a water outlet pipe 203, a connecting pipe 204, a mincing mechanism 3, a mincing box 301, a water inlet 302, a first valve 303, a first motor 304, a mincing rod 305, a water outlet 306, a second valve 307, a bifurcated pipeline 308, a third valve 309, a fourth valve 310, a wastewater box 4, a feeding mechanism 5, a feeding box 501, a box cover 502, a first feeding pipe 503, a high-temperature stirring mechanism 6, a first protection box 601, a first heating box 602, an additive feeding hole 603, a first heating wire 604, a first relay 605, a second motor 606, a stirring rod 607, a first discharging pipe 608, a fifth valve 609, a high-temperature enzymolysis mechanism 7, a second protection box 701, a second heating box 702, a second feeding pipe 703, a sixth valve 704, a second heating wire 705, a first, A second relay 706, a second discharging pipe 707, a seventh valve 708, a filtering mechanism 8, a second water pump 801, a third feeding pipe 802, a filtering tank 803, a filtering plate 804, a sealing plate 805, a cylinder 806, a connecting plate 807, a waste water outlet pipe 808, an eighth valve 809 and a rectangular opening 8031. 56

Detailed Description

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

The components of embodiments of the present invention generally described and illustrated in the figures herein may be arranged and designed in a wide variety of different configurations. Thus, the following detailed description of the embodiments of the present invention, presented in the figures, is not intended to limit the scope of the invention, as claimed, but is merely representative of selected embodiments of the invention.

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.

In the description of the present invention, it should be noted that the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", etc., indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplicity of description, but do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it should be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, e.g., as meaning either a fixed connection, a removable connection, or an integral connection; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

The invention provides active small molecule sheep placenta lyophilized powder production equipment which is shown by combining figures 1 to 4 and comprises a fixing mechanism 1, a clear water mechanism 2, a feeding mechanism 5, a stirring mechanism 3, a waste water tank 4, a high-temperature stirring mechanism 6, a high-temperature enzymolysis mechanism 7 and a filtering mechanism 8, wherein the clear water mechanism 2, the feeding mechanism 5, the stirring mechanism 3, the waste water tank 4, the high-temperature stirring mechanism 6, the high-temperature enzymolysis mechanism 7 and the filtering mechanism 8 are all arranged on the fixing mechanism 1, the feeding mechanism 5 and the clear water mechanism 2 are all connected with the stirring mechanism 3, the waste water tank 4 and the high-temperature stirring mechanism 6 are in a vertical connection state, the high-temperature stirring mechanism 6 and the high-temperature enzymolysis mechanism 7 are in a vertical connection state, the high-temperature enzymolysis mechanism 7 is connected with the filtering mechanism 8, and the fixing mechanism 1 is used for placing the clear water mechanism 2, Feed mechanism 5, stirring rubbing crusher constructs 3, waste water tank 4, high temperature rabbling mechanism 6, high temperature enzymolysis mechanism 7 and filtering mechanism 8, clear water mechanism 2 is used for providing the water that need add when sheep placenta element adds man-hour, clear water mechanism 2 still is used for equipment operation to accomplish the back and washs equipment, can transport the sheep placenta element that washs to stirring rubbing crusher constructs 3 in through feed mechanism 5, stirring rubbing crusher constructs 3 and is used for stirring the sheep placenta element and smashes to be the prosomillet meat and transports to high temperature rabbling mechanism 6 in, high temperature rabbling mechanism 6 is used for adding protease preparation and constantly stirs in the prosomillet meat that will stir the bits of broken bits and makes its fuse, high temperature enzymolysis mechanism 7 is used for carrying out high temperature enzymolysis to the prosomillet meat that the stirring fuses, filtering mechanism 8 is used for making the moisture in the prosomillet meat deposit.

The fixing mechanism 1 comprises a bottom fixing plate 101, a middle fixing plate 102, a top fixing plate 103 and four fixing columns 104, wherein the bottom fixing plate 101, the middle fixing plate 102 and the top fixing plate 103 are arranged in a manner of corresponding to each other in the vertical direction, the bottom ends of the four fixing columns 104 are respectively arranged at four corners above the bottom fixing plate 101, the top ends of the four fixing columns 104 penetrate through the middle fixing plate 102 and are arranged at four corners below the top fixing plate 103, the top fixing plate 103 is used for placing the clean water mechanism 2 and the mincing mechanism 3, the middle fixing plate 102 is used for placing the high-temperature stirring mechanism 6 and the waste water tank 4, the bottom fixing plate 101 is used for placing the high-temperature enzymolysis mechanism 7 and the filtering mechanism 8, and the fixing columns 104 are used for fixing the bottom fixing plate 101.

Clear water mechanism 2 includes clear water tank 201, first water pump 202, outlet pipe 203 and connecting pipe 204, clear water tank 201 sets up on top layer fixed plate 103, first water pump 202 sets up in clear water tank 201, the one end and the first water pump 202 of outlet pipe 203 are connected, the other end and the one end of connecting pipe 204 of outlet pipe 203 are connected, the other end and the mincing mechanism 3 of connecting pipe 204 are connected, clear water tank 201 is used for placing the clear water, first water pump 202 is used for transporting the clear water in the clear water tank 201 to outlet pipe 203 in, can transport the clear water to the connecting pipe 204 in through outlet pipe 203, can transport the mincing mechanism 3 with the clear water in through connecting pipe 204.

The mincing mechanism 3 comprises a mincing box 301, a water inlet 302, a first valve 303, a first motor 304, a mincing rod 305, a water outlet 306, a second valve 307, a forked pipeline 308, a third valve 309 and a fourth valve 310, wherein the mincing box 301 is arranged on a top layer fixing plate 103 and positioned at one side of a clean water box 201, the water outlet 306 is arranged above the mincing box 301, the first valve 303 is arranged in the water inlet 302, the water inlet 302 is connected with a connecting pipe 204, the first motor 304 is arranged above the mincing box 301 and positioned at one side of the water inlet 302, the output end of the first motor 304 is connected with the mincing rod 305, the mincing rod 305 is arranged in the mincing box 301, the water outlet 306 is arranged at the bottom of the mincing box 301, the water outlet 306 penetrates through the top layer fixing plate 103 and is connected with the forked pipeline 308, the forked pipeline 308 is arranged below the top layer fixing plate 103, the two ends of the branched pipeline 308 are respectively connected with the high-temperature stirring mechanism 6 and the waste water tank 4, the second valve 307 is arranged on the water outlet 306, the third valve 309 and the fourth valve 310 are both arranged on the branched pipeline 308 and located on one side of the high-temperature stirring mechanism 6, the fourth valve 310 is located on one side of the waste water tank 4, the mincing tank 301 is used for placing sheep placenta, the water inlet 302 is used for transporting clean water, the first valve 303 can open or close the water inlet 302, the first motor 304 is used for driving the mincing rod 305, the mincing rod 305 can stir and pulverize sheep placenta under the driving of the first motor 304, the water outlet 306 is used for enabling the minced sheep placenta to flow into the high-temperature stirring mechanism 6, the water outlet 306 is also used for enabling clean water to flow into the waste water tank 4, and the second valve 307 is used for controlling the opening or closing of the water outlet 306, the third valve 309 and the fourth valve 310 are used for controlling the opening and closing of the two ends of the branched pipe 308, respectively.

Feed mechanism 5 includes feeding case 501, case lid 502 and first inlet pipe 503, the one end and the crushing case 301 of first inlet pipe 503 are connected, the other end and the feeding case 501 of first inlet pipe 503 are connected, feeding case 501 sets up the one side at crushing case 301, case lid 502 sets up the top at feeding case 501, feeding case 501 is used for transporting sheepskin to first inlet pipe 503 in, case lid 502 is used for opening or closing feeding case 501, can transport sheepskin to crushing case 301 in through first inlet pipe 503.

The high-temperature stirring mechanism 6 comprises a first protection box 601, a first heating box 602, an additive feeding hole 603, a first heating wire 604, a first relay 605, a second motor 606, a stirring rod 607, a first discharging pipe 608 and a fifth valve 609, wherein the first protection box 601 is arranged on the middle fixing plate 102 and is positioned at one side of the wastewater box 4, the first heating box 602 is arranged in the first protection box 601, the top of the first heating box 602 is connected with the branched pipeline 308, the first heating wire 604 is arranged around the first heating box 602, the first relay 605 is arranged on the first protection box 601, the first relay 605 is connected with the first heating wire 604, the additive feeding hole 603 is arranged above the first heating box 602, the upper part of the additive feeding hole 603 penetrates through the first heating box 601 and the top fixing plate 103 and extends out of one end, the second motor 606 is arranged at the bottom of the first heating box 602, the stirring rod 607 is arranged in the first heating box 602, the first discharging pipe 608 is arranged at the bottom of the first heating box 602, the fifth valve 609 is arranged on the first discharging pipe 608, the first protection box 601 is used for protecting the first heating wire 604, the first relay 605 and the first heating box 602, the first relay 605 is used for enabling the first heating wire 604 to work, the first heating wire 604 is used for heating the first heating box 602, the first heating box 602 can enable the interior of the first heating box 602 to be in a high-temperature state through the heating of the first heating wire 604, the additive feeding port 603 is used for adding the protease preparation, the second motor 606 is used for driving the stirring rod 607, the stirring rod 607 is used for stirring and fusing the protease preparation, the lamb placenta and water, and the stirred mixture can be transported to the high-temperature enzymolysis mechanism 7 through the first discharging pipe 608, the fifth valve 609 is used to control the opening or closing of the first tapping pipe 608.

The high-temperature enzymolysis mechanism 7 comprises a second protection box 701, a second heating box 702, a second feeding pipe 703, a sixth valve 704, a second heating wire 705, a second relay 706, a second discharging pipe 707 and a seventh valve 708, the second protection box 701 is arranged on the bottom fixing plate 101, the second heating box 702 is arranged in the second protection box 701, the second feeding pipe 703 is arranged at the top of the second heating box 702, the sixth valve 704 is arranged on the second feeding pipe 703, the second heating wire 705 is arranged around the second heating box 702, the second heating wire 705 is connected with the relay, the second relay 706 is arranged on the second protection box 701, the second discharging pipe 707 is arranged at one side of the second heating box 702, the seventh valve is arranged on the second discharging pipe 707, the second protection box 701 is used for protecting the second heating wire 705, the second relay 706 and the second heating box 702, the second heating box 702 heats the water in the second heating box 702 through the driving of a second heating wire 705 and a second relay 706, so that the protease preparation, the lamb placenta broom corn millet and the water which are stirred in the first heating box 602 are subjected to enzymolysis in the second heating box 702, the second discharge pipe 707 is used for connecting the filtering mechanism 8, and the seventh valve 708 is used for controlling the opening or closing of the second discharge pipe 707.

The filtering mechanism 8 comprises a second water pump 801, a third feeding pipe 802, a filtering box 803, a filtering plate 804, a sealing plate 805, a cylinder 806, a connecting plate 807, a waste water outlet pipe 808 and an eighth valve 809, the second water pump 801 is arranged on the bottom fixing plate 101 and is positioned between the filtering box 803 and the second protection box 701, two working ends of the second water pump 801 are respectively connected with the second discharging pipe 707 and the third feeding pipe 802, the third connecting pipe 204 is connected with the filtering box 803, the filtering box 803 is arranged on the bottom fixing plate 101, the filtering plate 804 is arranged in the filtering box 803, the filtering box 803 is provided with a rectangular opening 8031, the sealing plate 805 is arranged on one side of the rectangular opening 8031, the connecting plate 805 is arranged on one side of the sealing plate 805, the cylinder 806 is arranged at the bottom of the connecting plate 807, an output end of the cylinder 806 is connected with the connecting plate 807, the waste water outlet pipe 808 is arranged on one side of the filter tank 803 and is located at the bottom of the sealing plate 805, the eighth valve 809 is arranged on the waste water outlet pipe 808, the second water pump 801 is used for transporting the enzymolyzed meat in the second heating tank 702 into the filter tank 803 through the second discharge pipe 707 and the third feed pipe 802, the filter plate 804 is used for precipitating the meat, the water precipitated in the meat flows into the bottom of the filter tank 803 through the filter plate 804, the water at the bottom of the filter tank 803 flows out through the waste water outlet pipe 808, the eighth valve 809 is used for controlling the opening and closing of the waste water outlet pipe 808, the air cylinder 806 is used for driving the connecting plate 807, the connecting plate can drive the sealing plate 805 to vertically move, and the worker can take out the meat through a rectangular opening groove.

The working principle is that the sheep placenta is put into the mincing box 301 through the feeding box 501 and is crushed through the crushing rod 305, after the crushing is finished, a certain proportion of water is added through the driving of the first water pump 202, the first valve 303 and the second valve 307 are opened to enable the broom corn meat to be subjected to the first heating box 602, the protease preparation is added through the additive feeding port 603, the protease preparation, the water and the broom corn meat are stirred through the driving of the second motor 606, the first relay 605 drives the first heating wire 604 to operate, the first heating wire 604 enables the first heating box 602 to be heated, the stirring temperature is increased, after the stirring is finished, the broom corn meat enters the second heating box 702 through the fifth valve 609, when the broom corn meat is in the second heating box 702, a certain amount of water is injected through the first water pump 202, the mincing box 301 and the first heating box 602 enter the second heating box 702, the water is heated through the second relay 706 and the second heating wire 705 to enable the protease preparation to be fully inactivated, then obtaining the enzymatic hydrolysate, transporting the enzymatic hydrolysate into the filter tank 803 through the second water pump 801 to precipitate the enzymatic hydrolysate, opening the eighth valve 809 after the precipitation is finished, discharging the wastewater through the wastewater outlet pipe 808, then driving the connecting plate 807 through the air cylinder 806 to open the sealing plate 805, finally taking out the precipitated enzymatic hydrolysate from the rectangular opening hole 8031 by a worker, and finally injecting enough clear water through the first water pump 202 to clean the mincing tank 301, the first heating tank 602, the second heating tank 702 and the filter tank 803. Above with solving prior art and exist in the extraction process and cause this internal nutrition flowing water of sheep placenta essence when drawing sheep placenta essence, and can't need artifical the washing to equipment self-cleaning after drawing the completion, and equipment cleaning is too troublesome, has influenced the operating efficiency and has been the purpose.

Finally, it should be noted that: the above embodiments are only used to illustrate the technical solution of the present invention, and not to limit the same; while the invention has been described in detail and with reference to the foregoing embodiments, those skilled in the art will appreciate that; the technical solutions described in the foregoing embodiments may still be modified, or some or all of the technical features may be equivalently replaced; and the modifications or the substitutions do not make the essence of the corresponding technical solutions depart from the scope of the technical solutions of the embodiments of the present invention.