CN215693223U - Membrane separation draws xylo-oligosaccharide device - Google Patents

Abstract

The utility model discloses a device for extracting xylo-oligosaccharide by membrane separation, which is characterized in that: the crushing cylinder is of a hollow cylinder structure, the crushing cylinder is internally provided with a vertically-arranged crushing cutter head, the bottom side face of the crushing cylinder is provided with a vertically-arranged crushing motor, the crushing motor is connected with the crushing cutter head in a matched mode, the right side face of the crushing cylinder is provided with a discharging interface, the bottom position of the crushing cylinder is provided with an outer frame, the left side face of the outer frame is provided with an electric cabinet, the top part of the crushing cylinder is provided with a discharging motor, the discharging motor is arranged at the right side position of the crushing cylinder and is connected with the discharging interface in a matched mode, the front side face of the discharging motor is provided with a booster pump, the right side face of the booster pump is provided with a separating cylinder, the separating cylinder is arranged at the inner relative position of the right side face of the outer frame, the top part of the separating cylinder is provided with a sealing cover plate, and the top part of the sealing cover plate is provided with a pressure gauge, and the crushing cylinder has the advantages that: the method has the advantages of high extraction efficiency, high controllability and stable equipment operation.

Description

Membrane separation draws xylo-oligosaccharide device

Technical Field

The utility model belongs to the technical field of loading and extracting devices, and particularly relates to a device for extracting xylooligosaccharide through membrane separation.

Background

The operation of the membrane separation equipment is a pressure-driven membrane separation process, which is a method for separating xylooligosaccharide according to the difference of molecular weights between high molecular solutes or between high molecular solutes and low molecular solutes, the application range of the xylooligosaccharide is very wide in life, the xylooligosaccharide is functional polysaccharide formed by combining 2-7 xylose molecules, the extraction raw materials of the xylooligosaccharide are mostly extracted from corncobs, cottonseed hulls and other raw materials, the existing extraction equipment has single function and low conversion rate of the xylooligosaccharide, the extraction effect is achieved by matching various equipment, the mode has very high manufacturing cost and very low production efficiency, a large amount of labor cost and mechanical cost are consumed, the practicability is not strong, and the actual production is combined, so the membrane separation and extraction device for the xylooligosaccharide achieves good research and development effects, and the device is integrated and convenient to operate, the controllability is high.

SUMMERY OF THE UTILITY MODEL

The utility model provides a device for extracting xylo-oligosaccharide by membrane separation, which has high extraction efficiency, safety, stability and convenient use in actual extraction.

In order to solve the technical problems, the utility model adopts the following technical scheme:

a device for extracting xylo-oligosaccharide by membrane separation comprises a crushing barrel, wherein the crushing barrel is of a hollow cylindrical structure, a vertically arranged crushing cutter head is arranged inside the crushing barrel, a vertically arranged crushing motor is arranged on the bottom side surface of the crushing barrel, the crushing motor is matched and connected with the crushing cutter head, a discharging interface is arranged at the opposite position of the right side surface of the crushing barrel, an outer frame is arranged at the bottom position of the crushing barrel, an electric cabinet is arranged on the left side surface of the outer frame, a discharging motor is arranged at the opposite position of the top of the crushing barrel, the discharging motor is arranged at the right side position of the crushing barrel, the discharging motor is matched and connected with the discharging interface, a booster pump is arranged at the opposite position of the front side surface of the discharging motor, a separating barrel is arranged at the opposite position of the right side surface of the booster pump, the separating barrel is arranged at the opposite position inside the right side surface of the outer frame, a sealing cover plate is arranged at the top of the separating barrel, a pressure gauge is arranged at the top of the sealing cover plate, and a feeding interface is arranged at the opposite position of the rear side surface of the pressure gauge, the feeding interface is connected with the discharging motor in a matched mode, a pressure interface is arranged at the relative position of the front side face of the pressure gauge, the pressure interface is connected with the booster pump in a matched mode, a molecular diaphragm is arranged at the relative position of the inner portion of the separating cylinder, a discharge valve is arranged at the outer rear side face of the molecular diaphragm, a plurality of separating pipelines which are transversely and uniformly arranged are arranged at the outer left side face of the molecular diaphragm, a plurality of scouring pipelines which are transversely and uniformly arranged are arranged at the relative position of the top of each separating pipeline, the scouring pipelines and the separating pipelines are communicated with the left side face of the separating cylinder, a separating motor is arranged at the relative position of the rear portion of each separating pipeline, the separating pipelines and the separating motors are connected in a matched mode, a xylo-oligosaccharide collecting cylinder is arranged at the rear portion of each scouring pipeline, a scouring motor is arranged at the relative position of the rear portion of each scouring pipeline, the scouring pipelines and the scouring motors are connected in a matched mode, and a water tank is arranged at the bottom of each scouring motor.

Further, the outer diameter size of the sealing cover plate is matched with the relative position size of the upper part of the inner diameter of the separation cylinder.

Furthermore, the separation pipeline acts through a separation motor, the separation motor is communicated with the interior of the xylo-oligosaccharide collecting cylinder, and the flushing pipeline acts through a flushing motor, so that the flushing motor is communicated with the interior of the water tank.

Furthermore, the molecular diaphragm is arranged at the bottom of the separating cylinder, the height of the molecular diaphragm is higher than that of the separating pipeline, and the height of the molecular diaphragm is lower than that of the flushing pipeline.

Furthermore, the crushing cutter head rotates through a crushing motor connected with the bottom, and the discharging port is communicated with the feeding port through a pipeline connected with the discharging motor.

Compared with the prior art, the utility model has the beneficial effects that:

(1) traditional xylo-oligosaccharide draws equipment function singleness, the concentration that extracts is not high, and efficiency is very low, and this design will draw the function integrated as an organic whole, has improved the work efficiency who draws, can in time adjust according to the difference of raw materials, adapts to various raw materials and draws, and practicality is stronger.

(2) Every group station all can the independent control, and the controllability is good, and the long-time process of drawing can lead to blockking up the influence and draw, and this design still designs has built-in belt cleaning device, need not to take apart artifical clearance, has guaranteed the operation of not shutting down of equipment, and efficiency is more high-efficient, facilitates the use.

Drawings

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

FIG. 2 is a schematic view of a milling drum;

FIG. 3 is a schematic view of the overall structure of the extraction apparatus;

fig. 4 is a view showing the internal structure of the separation cylinder.

Description of the drawings: 1. the device comprises a discharging port, a discharging motor, a feeding port, a pressure gauge, a pressure port, a pressure interface, a frame, a separating cylinder, a booster pump, a flushing pipeline, a separating pipeline, a power cabinet, a crushing cylinder, a crushing motor, a crushing cutter head, a separation motor, a xylo-oligosaccharide collecting cylinder, a washing motor, a water tank, a sealing cover plate, a molecular diaphragm and a discharge valve, wherein the discharging port is 2, the feeding port is 3, the pressure gauge is 4, the pressure interface is 5, the outer frame is 6, the separating cylinder is 7, the booster pump is 8, the washing pipeline is 9, the separating pipeline is 10, the power cabinet is 11, the crushing cylinder is 12, the crushing motor is 13, the crushing cutter head is 14, the separating motor is 15, the xylo-oligosaccharide collecting cylinder is 16, the washing motor is 17, the water tank is 18, the sealing cover plate is 19, the molecular diaphragm is 20, and the discharge valve is 21.

Detailed Description

As shown in figures 1 to 4, a device for extracting xylo-oligosaccharide by membrane separation comprises a crushing barrel 12, wherein the crushing barrel 12 is of a hollow cylindrical structure, a vertically arranged crushing cutter head 14 is arranged inside the crushing barrel 12, a vertically arranged crushing motor 13 is arranged on the bottom side surface of the crushing barrel 12, the crushing motor 13 is matched and connected with the crushing cutter head 14, a discharging port 1 is arranged at the right side surface of the crushing barrel 12, an outer frame 6 is arranged at the bottom position of the crushing barrel 12, an electric cabinet 11 is arranged on the left side surface of the outer frame 6, a discharging motor 2 is arranged at the top relative position of the crushing barrel 12, the discharging motor 2 is arranged at the right side position of the crushing barrel 12, the discharging motor 2 is matched and connected with the discharging port 1, a booster pump 8 is arranged at the front side surface relative position of the booster pump 8, a separating barrel 7 is arranged at the right side surface relative position of the outer frame 6, a sealing cover plate 19 is arranged at the top of the separating barrel 7, the top of a sealing cover plate 19 is provided with a pressure gauge 4, the back side face of the pressure gauge 4 is provided with a feeding interface 3 at a relative position, the feeding interface 3 is in fit connection with a discharging motor 2, the front side face of the pressure gauge 4 is provided with a pressure interface 5 at a relative position, the pressure interface 5 is in fit connection with a booster pump 8, the inside of a separating cylinder 7 is provided with a molecular diaphragm 20 at a relative position, the outside back side face of the molecular diaphragm 20 is provided with a discharging valve 21, the outside left side face of the molecular diaphragm 20 is provided with a plurality of separating pipelines 10 which are transversely and uniformly arranged, the top relative position of the separating pipelines 10 is provided with a plurality of scouring pipelines 9 which are transversely and uniformly arranged, the scouring pipelines 9 and 10 are communicated with the left side face of the separating cylinder 7, the back part of the separating pipeline 10 is provided with a separating motor 15 at a relative position, the separating pipeline 10 is in fit connection with the separating motor 15, the back part of the separating motor 15 is provided with a xylo-oligosaccharide collecting cylinder 16, and the scouring motor 17 is arranged at the back part of the scouring pipeline 9, the flushing pipeline 9 is connected with a flushing motor 17 in a matching way, and a water tank 18 is arranged at the bottom of the flushing motor 17.

The outer diameter of the sealing cover plate 19 is matched with the relative position of the upper part of the inner diameter of the separating cylinder 7.

The separation pipeline 10 acts through the separation motor 15, the separation motor 15 is communicated with the interior of the xylo-oligosaccharide collecting cylinder 16, and the flushing pipeline 9 acts through the flushing motor 17, so that the flushing motor 17 is communicated with the interior of the water tank 18.

The molecular diaphragm 20 is arranged at the bottom position inside the separating cylinder 7, the height of the molecular diaphragm 20 is higher than that of the separating pipeline 10, and the height of the molecular diaphragm 20 is lower than that of the flushing pipeline 9.

The crushing cutter head 14 rotates through a crushing motor 13 connected with the bottom, and the discharging port 1 is communicated with the feeding port 3 through a pipeline connected with the discharging motor 2.

The working process is as follows: pouring corncobs, cotton seed shells and other raw materials into a crushing barrel 12, adding liquid water in the same proportion according to the injected amount, starting a crushing motor 13, driving a crushing cutter head 14 to rotate through the crushing motor 13, crushing the raw materials in the crushing barrel 12 at the moment, operating a discharging motor 2 after crushing to a certain concentration, discharging the crushed raw materials in the crushing barrel 12 through a discharging interface 1, conveying the crushed raw materials to a feeding interface 3 through a pipeline, then flowing into a separation barrel 7, stopping the discharging motor 2 after injecting a certain amount, starting a booster pump 8 to pressurize the inside of the separation barrel 7 at the moment, communicating air pressure generated by the operation of the booster pump 8 with a pressure interface 5 through an air pipe, observing the pressure value of a pressure gauge 4 to obtain the internal pressure of the separation barrel 7, operating a separation motor 15 when the pressure is constant, communicating the separation motor with the separation pipeline 10 through the pressure interface 5, extracting the air outwards and conveying the air pressure into a xylo-oligosaccharide collection barrel 16, after extracting a certain time, because the crushed aggregates can block up the extraction effect on attached to 20 top surfaces of molecule diaphragm, the operation erodees motor 17 this moment, through erodeing motor 17 to 18 inside extraction liquid water of water tank pour into the knockout drum 7 inside through erodeing pipeline 9, wash 20 tops of molecule diaphragm, guarantee to continue to separate and extract the operation, draw and discharge the inside residue of knockout drum 7 through the bleeder valve 21 of connecting 7 rear portions of knockout drum after accomplishing, the cooperation erodees motor 17 and pours into and carry out inside washing, guarantee next time can normal use.

Claims (5)

1. The utility model provides a membrane separation draws xylo-oligosaccharide device which characterized in that: comprises a crushing barrel (12), the crushing barrel (12) is of a hollow cylinder structure, a vertically arranged crushing cutter head (14) is arranged inside the crushing barrel (12), a vertically arranged crushing motor (13) is arranged on the bottom side surface of the crushing barrel (12), the crushing motor (13) is matched and connected with the crushing cutter head (14), a discharging port (1) is arranged at the right side surface relative position of the crushing barrel (12), an outer frame (6) is arranged at the bottom position of the crushing barrel (12), an electric cabinet (11) is arranged on the left side surface of the outer frame (6), a discharging motor (2) is arranged at the top relative position of the crushing barrel (12), the discharging motor (2) is arranged at the right side position of the crushing barrel (12), the discharging motor (2) is matched and connected with the discharging port (1), a booster pump (8) is arranged at the front side surface relative position of the discharging motor (2), a separating barrel (7) is arranged at the right side surface relative position of the booster pump (8), the separation cylinder (7) is arranged at the inner relative position of the right side surface of the outer frame (6), a sealing cover plate (19) is arranged at the top of the separation cylinder (7), a pressure gauge (4) is arranged at the top of the sealing cover plate (19), a feeding interface (3) is arranged at the relative position of the rear side surface of the pressure gauge (4), the feeding interface (3) is matched and connected with the discharging motor (2), a pressure interface (5) is arranged at the relative position of the front side surface of the pressure gauge (4), the pressure interface (5) is matched and connected with a booster pump (8), a molecular diaphragm (20) is arranged at the inner relative position of the separation cylinder (7), a discharging valve (21) is arranged at the outer rear side surface of the molecular diaphragm (20), a plurality of separation pipelines (10) which are transversely and uniformly arranged are arranged on the outer left side surface of the molecular diaphragm (20), a plurality of scouring pipelines (9) which are transversely and uniformly arranged are arranged on the relative position of the top of the separation pipelines (10), the scouring pipelines (9) and the separation pipelines (10) are communicated with the left side surface of the separation cylinder (7), separation motor (15) are equipped with at separation pipeline (10) rear portion relative position, and separation pipeline (10) and separation motor (15) cooperation are connected, and separation motor (15) rear portion is equipped with xylo-oligosaccharide collecting vessel (16), erodees pipeline (9) rear portion relative position and is equipped with erodees motor (17), erodees pipeline (9) and erodees motor (17) cooperation and connect, and it is equipped with water tank (18) to erode motor (17) bottom position.

2. The device for extracting xylo-oligosaccharide by membrane separation according to claim 1, characterized in that: the outer diameter of the sealing cover plate (19) is matched with the relative position size of the upper part of the inner diameter of the separating cylinder (7).

3. The device for extracting xylo-oligosaccharide by membrane separation according to claim 1, characterized in that: the separation pipeline (10) acts through the separation motor (15), the separation motor (15) is communicated with the interior of the xylo-oligosaccharide collection cylinder (16), and the flushing pipeline (9) acts through the flushing motor (17), and the flushing motor (17) is communicated with the interior of the water tank (18).

4. The device for extracting xylo-oligosaccharide by membrane separation according to claim 1, characterized in that: the molecular diaphragm (20) is arranged at the bottom of the inner part of the separation cylinder (7), the height of the molecular diaphragm (20) is higher than that of the separation pipeline (10), and the height of the molecular diaphragm (20) is lower than that of the flushing pipeline (9).

5. The device for extracting xylo-oligosaccharide by membrane separation according to claim 1, characterized in that: the crushing cutter head (14) rotates through a crushing motor (13) connected with the bottom, and the discharging port (1) is communicated with the feeding port (3) through a pipeline connected with the discharging motor (2).

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