Quantitative proportioning device for fructooligosaccharide processing saccharifying enzyme

By designing a quantitative mixing device for saccharifying enzymes that includes a reciprocating mechanism and a plugging mechanism, the problems of low efficiency and error caused by manual measurement in the existing technology are solved. This enables quantitative mixing and flexible adjustment of saccharifying enzymes, thereby improving the accuracy and efficiency of fructooligosaccharide production.

CN224358369UActive Publication Date: 2026-06-16YIERBAITE (HUNAN) BIOTECHNOLOGY CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
YIERBAITE (HUNAN) BIOTECHNOLOGY CO LTD
Filing Date
2025-07-15
Publication Date
2026-06-16

AI Technical Summary

Technical Problem

Existing quantitative mixing devices for fructooligosaccharide processing saccharifying enzymes rely on manual measuring tools, resulting in low mixing efficiency and the presence of human error.

Method used

A quantitative dispensing device for saccharifying enzymes was designed, which includes a reciprocating mechanism and a plugging mechanism. The device achieves quantitative dispensing of saccharifying enzymes by cooperating with a motor-driven wheel and a limit pin, and different dispensing ratios can be achieved by changing the wheel.

Benefits of technology

It improved the accuracy of saccharifying enzyme ratio and the adaptability of the equipment, reduced human error, and increased the efficiency of fructooligosaccharide production.

✦ Generated by Eureka AI based on patent content.

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Abstract

The application discloses a quantitative proportioning device for saccharifying enzyme in fructooligosaccharide processing, and relates to the field of fructooligosaccharide processing.The device comprises a storage tank, a reciprocating mechanism arranged in the storage tank, and a plug-in mechanism arranged in the reciprocating mechanism; the reciprocating mechanism comprises a wheel disc and a push-pull plate movably arranged in the storage tank.The device can quantitatively discharge the saccharifying enzyme in the storage tank by the action of the reciprocating mechanism, and the running of a control motor is controlled; the motor output end drives the wheel disc to rotate, the wheel disc drives a limiting pin to move in a straight groove plate, the straight groove plate moves transversely in the movement of the limiting pin, thereby driving the connecting rod to move transversely and reciprocally, and the connecting rod drives the limiting pin to move reciprocally; after the push-pull plate is separated from one side of the storage tank, the saccharifying enzyme flows downwards and is introduced into a program of fructooligosaccharide processing through a discharging groove, the device has the action of quantitatively discharging the saccharifying enzyme, and the precision of saccharifying enzyme proportioning in the fructooligosaccharide processing is improved.
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Description

Technical Field

[0001] This utility model relates to the field of fructooligosaccharide processing technology, and in particular to a device for quantitatively proportioning saccharifying enzymes in fructooligosaccharide processing. Background Technology

[0002] Fructooligosaccharides (FOS), as a functional dietary fiber, are widely used in food, health products and other fields. They have significant effects on regulating intestinal flora, lowering blood lipids and improving glucose metabolism, and market demand continues to grow. As a key enzyme preparation in the production process of FOS, adjusting the appropriate ratio of saccharifying enzymes is one of the key steps.

[0003] In the process of producing fructooligosaccharides using saccharifying enzymes, the saccharifying enzymes are placed in a proportioning device, and the operation of the proportioning device is controlled. According to production needs, the saccharifying enzymes are added to the fructooligosaccharide production process.

[0004] Existing quantitative mixing devices for fructooligosaccharide processing mostly require manual measurement using measuring cylinders and balances during the mixing process, which reduces mixing efficiency and introduces human error. Therefore, a quantitative mixing device for fructooligosaccharide processing is proposed. Utility Model Content

[0005] (a) Technical problems to be solved

[0006] To address the problems existing in the prior art, this utility model provides a quantitative proportioning device for fructooligosaccharide processing saccharifying enzymes.

[0007] (II) Technical Solution

[0008] To achieve the above objectives, this utility model is implemented through the following technical solution: a quantitative proportioning device for fructooligosaccharide processing saccharifying enzyme, comprising a storage tank, wherein a reciprocating mechanism is provided inside the storage tank, and a plug-in mechanism is provided inside the reciprocating mechanism.

[0009] As a preferred embodiment of the fructooligosaccharide processing saccharifying enzyme quantitative proportioning device of this utility model, the reciprocating mechanism includes a wheel, a push-pull plate is movably installed inside the storage box, a connecting rod is fixedly connected to one side of the push-pull plate, a straight groove plate is provided on one side of the connecting rod, and a limit pin is fixedly connected to one side of the wheel at a non-center position.

[0010] As a preferred embodiment of the fructooligosaccharide processing saccharifying enzyme quantitative proportioning device of the present invention, the plug-in mechanism includes a leveling block fixedly installed on the outside of the motor output end, plug-in rods symmetrically arranged inside the leveling block, plug-in blocks adapted to the motor output end symmetrically arranged on one side of the wheel, an L-shaped pressure block arranged inside the leveling block, and a spring fixedly connected to one side of the L-shaped pressure block.

[0011] In a preferred embodiment of the fructooligosaccharide processing saccharifying enzyme quantitative proportioning device of the present invention, a square hole adapted to the push-pull plate is provided on one side of the storage box, the push-pull plate is slidably connected inside the square hole, and the limiting pin is slidably connected inside the straight groove plate.

[0012] In a preferred embodiment of the saccharifying enzyme quantitative proportioning device for processing fructooligosaccharides described in this utility model, an L-shaped plate is fixedly installed at the bottom of the storage box, a motor is provided at the top of the L-shaped plate, a wheel is fixedly installed at the output end of the motor, a guide plate is fixedly installed on the inner surface of the storage box, and a feeding trough is fixedly connected to the bottom of the storage box.

[0013] In a preferred embodiment of the fructooligosaccharide processing saccharifying enzyme quantitative proportioning device of the present invention, the top of the leveling block, the motor and the plug-in block are symmetrically provided with insertion holes adapted to the plug-in rods, the plug-in rods are sequentially inserted into the insertion holes, the output end of the motor is provided with a slot adapted to the plug-in block, and the plug-in block is movably engaged in the slot.

[0014] In a preferred embodiment of the fructooligosaccharide processing saccharifying enzyme quantitative proportioning device of the present invention, the top of the leveling block is provided with a groove adapted to the L-shaped pressure block, the L-shaped pressure block is slidably connected inside the groove, the top of the plug rod is fixedly installed with a limiting plate, and the L-shaped pressure block is located on the top of the limiting plate.

[0015] In a preferred embodiment of the saccharifying enzyme quantitative proportioning device for fructooligosaccharide processing described in this utility model, a servo telescopic cylinder is fixedly installed at the bottom of the L-shaped plate, a top block is fixedly connected to the output end of the servo telescopic cylinder, a sliding hole adapted to the top block is opened at the top of the L-shaped plate, the top block is slidably connected inside the sliding hole, and the top of the top block is fixedly connected to the bottom of the motor.

[0016] (III) Beneficial Effects

[0017] This invention provides a device for quantitatively dispensing saccharifying enzymes in the processing of fructooligosaccharides. It has the following beneficial effects:

[0018] 1. Through the action of the reciprocating mechanism, the saccharifying enzyme in the storage box can be quantitatively fed. The operation of the motor is controlled, and the motor output drives the wheel to rotate. The wheel drives the limit pin to move in the straight groove plate. During the movement of the limit pin, the straight groove plate moves laterally, thereby driving the connecting rod to move laterally reciprocally. The connecting rod extends and retracts in a reciprocating manner. After the push-pull plate is separated from the storage box on one side, the saccharifying enzyme will flow downward and be introduced into the oligofructose processing program through the feeding trough. It has the function of quantitatively feeding the saccharifying enzyme and improving the accuracy of the saccharifying enzyme ratio in the oligofructose processing process.

[0019] 2. The plug-in mechanism facilitates the replacement of larger diameter discs, increasing the amount of saccharifying enzyme falling and thus increasing the proportion of saccharifying enzyme used in fructooligosaccharide processing. The L-shaped pressure block is manually pushed outward from the limiting plate, and then the limiting plate is pulled upward. The limiting plate drives two plug-in rods to move upward from the motor output end, the plug-in block, and the leveling block's insertion holes. After the plug-in rods are fully pulled out, the disc is pulled outward, pulling the plug-in block out of the motor output end and sliding it onto the larger diameter disc. The reverse process is repeated to fix the plug-in block in the motor output end. Then, the servo telescopic cylinder is controlled to push the motor outward through the top block, causing the limiting pin on the larger diameter disc to engage in the straight groove plate. This allows for adjustments to the saccharifying enzyme feeding ratio according to the required proportions, improving the device's adaptability. Attached Figure Description

[0020] To more clearly illustrate the technical solutions in the embodiments of this utility model, the drawings used in the description of the embodiments will be briefly introduced below. Obviously, the drawings described below are only some embodiments of this utility model. For those skilled in the art, other drawings can be obtained based on these drawings without creative effort.

[0021] Figure 1 This is a schematic diagram of the overall structure of this utility model.

[0022] Figure 2 This is a partial cross-sectional schematic diagram of the reciprocating mechanism of this utility model.

[0023] Figure 3 This is a partial structural schematic diagram of the reciprocating mechanism and the insertion mechanism of this utility model.

[0024] Figure 4 This is an exploded schematic diagram of the plug-in mechanism of this utility model.

[0025] In the diagram, 1 is the storage bin; 2 is the reciprocating mechanism; 201 is the push-pull plate; 202 is the discharge chute; 203 is the guide plate; 204 is the L-shaped plate; 205 is the connecting rod; 206 is the motor; 207 is the wheel; 208 is the straight groove plate; 209 is the limit pin; 3 is the insertion mechanism; 301 is the leveling block; 302 is the insertion rod; 303 is the limit plate; 304 is the spring; 305 is the L-shaped pressure block; 306 is the insertion block; 307 is the servo telescopic cylinder; and 308 is the top block. Detailed Implementation

[0026] The technical solutions of the present invention will be clearly and completely described below with reference to the accompanying drawings of the embodiments of the present invention.

[0027] Example 1

[0028] Reference Figure 1 , Figure 2 and Figure 3 This is the first embodiment of the present invention. This embodiment provides a quantitative proportioning device for fructooligosaccharide processing saccharifying enzyme, including a storage tank 1, a reciprocating mechanism 2 inside the storage tank 1, and a plugging mechanism 3 inside the reciprocating mechanism 2.

[0029] The reciprocating mechanism 2 includes a wheel 207, a push-pull plate 201 is movably installed inside the storage box 1, a connecting rod 205 is fixedly connected to one side of the push-pull plate 201, a straight groove plate 208 is provided on one side of the connecting rod 205, and a limit pin 209 is fixedly connected to one side of the wheel 207 at a non-center position.

[0030] Specifically, a square hole adapted to the push-pull plate 201 is provided on one side of the storage box 1. The push-pull plate 201 is slidably connected inside the square hole, and the limiting pin 209 is slidably connected inside the straight groove plate 208. When the wheel 207 drives the straight groove plate 208 to rotate, since the straight groove plate 208 is not at the center of the wheel 207, the limiting pin 209 can drive the straight groove plate 208 to move laterally when it rotates in a circle. Under the action of the straight groove plate 208, the vertical movement of the limiting pin 209 is counteracted, and only the limiting pin 209 is allowed to drive the straight groove plate 208 to move laterally.

[0031] Specifically, an L-shaped plate 204 is fixedly installed at the bottom of the storage bin 1, a motor 206 is installed at the top of the L-shaped plate 204, a wheel 207 is fixedly installed at the output end of the motor 206, a guide plate 203 is fixedly installed on the inner surface of the storage bin 1, and a discharge chute 202 is fixedly connected to the bottom of the storage bin 1. Under the action of the guide plate 203, the saccharifying enzyme in the storage bin 1 has a certain downward flow effect, preventing the saccharifying enzyme from accumulating and the discharge from being incomplete.

[0032] Furthermore, the operation of the control motor 206 is controlled. The output end of the motor 206 drives the wheel 207 to rotate. The wheel 207 drives the limit pin 209 to move in the straight groove plate 208. During the movement of the limit pin 209, the straight groove plate 208 moves laterally, thereby driving the connecting rod 205 to move laterally back and forth. The connecting rod 205 drives the push-pull plate 201 to extend and retract in the storage box 1 in a reciprocating manner. After the push-pull plate 201 is separated from the storage box 1 on one side, the saccharifying enzyme will flow downward and be introduced into the oligofructose processing program through the feeding trough 202.

[0033] Example 2

[0034] Reference Figure 3 and Figure 4 This is the second embodiment of the present invention, which is based on the previous embodiment. The plug-in mechanism 3 includes a flat block 301 fixedly installed on the outside of the output end of the motor 206. A plug-in rod 302 is symmetrically arranged inside the flat block 301. A plug-in block 306 adapted to the output end of the motor 206 is symmetrically arranged on one side of the wheel 207. An L-shaped pressure block 305 is arranged inside the flat block 301. A spring 304 is fixedly connected to one side of the L-shaped pressure block 305.

[0035] Specifically, the leveling block 301, the motor 206, and the plug-in block 306 all have symmetrically arranged insertion holes on their tops that are adapted to the plug-in rods 302. The plug-in rods 302 are inserted into the insertion holes in sequence. The output end of the motor 206 has a slot adapted to the plug-in block 306. The plug-in block 306 is movably engaged in the slot. After the plug-in block 306 is engaged in the slot of the motor 206, both plug-in rods 302 are inserted into the corresponding insertion holes, which can fix the wheel 207 on one side of the motor 206 and facilitate the replacement of the wheel 207.

[0036] Specifically, the top of the leveling block 301 is provided with a groove that is adapted to the L-shaped pressure block 305. The L-shaped pressure block 305 is slidably connected inside the groove. The top of the plug rod 302 is fixedly installed with a limiting plate 303. The L-shaped pressure block 305 is located on the top of the limiting plate 303. Under the action of the spring 304, the L-shaped pressure block 305 is pushed to the center of the top of the limiting plate 303, and the limiting plate 303 is fixed on the top of the leveling block 301. When the output end of the motor 206 rotates, it prevents the plug rod 302 from falling out of the plug rod 302 and the plug hole of the motor 206.

[0037] Specifically, a servo telescopic cylinder 307 is fixedly installed at the bottom of the L-shaped plate 204. A top block 308 is fixedly connected to the output end of the servo telescopic cylinder 307. A sliding hole adapted to the top block 308 is opened at the top of the L-shaped plate 204. The top block 308 is slidably connected inside the sliding hole. The top of the top block 308 is fixedly connected to the bottom of the motor 206. When replacing the larger diameter wheel 207, the operation of the servo telescopic cylinder 307 is controlled to push the top block 308 outward in the sliding hole of the L-shaped plate 204. The limit pin 209 on the larger wheel 207 is engaged in the straight groove plate 208, increasing the stroke of the connecting rod 205, thereby increasing the amount of saccharifying enzyme falling each time.

[0038] Furthermore, manually push the L-shaped pressure block 305 outward from the limiting plate 303, then pull the limiting plate 303 upward. The limiting plate 303 drives the two plug rods 302 to move upward from the output end of the motor 206, the plug block 306, and the leveling block 301. After the plug rods 302 are fully pulled out, pull the wheel 207 outward to pull the plug block 306 out from the output end of the motor 206 and slide it onto the larger diameter wheel 207. Similarly, fix the plug block 306 in the output end of the motor 206. Under the action of the spring 304, push the L-shaped pressure block 305 to the top center of the limiting plate 303. Then control the servo telescopic cylinder 307 to run, and push the motor 206 outward through the top block 308 so that the limiting pin 209 on the larger diameter wheel 207 can be inserted into the straight groove plate 208.

[0039] Working principle: The device is connected to an external power supply and controller via a wiring harness. The saccharifying enzyme required for fructooligosaccharide processing is added to the storage tank 1. The operation of motor 206 is controlled, and the output of motor 206 drives the wheel 207 to rotate. The wheel 207 drives the limiting pin 209 to move within the straight groove plate 208. During the movement of the limiting pin 209, the straight groove plate 208 moves laterally, thereby driving the connecting rod 205 to move laterally reciprocally. The connecting rod 205 drives the push-pull plate 201 to extend and retract in the storage tank 1 in a reciprocating manner. After one side of the push-pull plate 201 disengages from one side of the storage tank 1, the saccharifying enzyme flows downwards. The saccharifying enzyme used for fructooligosaccharide processing is quantitatively added through the feeding trough 202. When it is necessary to increase the amount of saccharifying enzyme added, the L-shaped pressure block 305 is manually pushed outwards from the limiting plate 303, and then the limiting plate 303... Pulling upwards causes the limiting plate 303 to move the two plug rods 302 upwards from the output end of the motor 206, the plug block 306, and the leveling block 301. After the plug rods 302 are fully pulled out, the wheel 207 is pulled outwards, pulling the plug block 306 out from the output end of the motor 206 and sliding it onto the larger diameter wheel 207. The reverse is also true, fixing the plug block 306 in the output end of the motor 206. Under the action of the spring 304, the L-shaped pressure block 305 is pushed to the top center of the limiting plate 303. Then, the servo telescopic cylinder 307 is controlled to run, pushing the motor 206 outwards through the top block 308, so that the limiting pin 209 on the larger diameter wheel 207 is engaged in the straight groove plate 208. The motor 206 is controlled to run again, with the same principle as above. The opening of the push-pull plate 201 is enlarged to increase the amount of saccharifying enzyme falling.

[0040] It should be noted that in this paper, relational terms such as first and second are used only to distinguish one entity or operation from another entity or operation, and do not necessarily require or imply any such actual relationship or order between these entities or operations.

Claims

1. A device for quantitatively dispensing fructooligosaccharide processing saccharifying enzymes, comprising a storage tank (1), characterized in that: The storage box (1) is equipped with a reciprocating mechanism (2), and the reciprocating mechanism (2) is equipped with a plug-in mechanism (3). Reciprocating mechanism (2); including a wheel (207), a push-pull plate (201) is movably installed inside the storage box (1), a connecting rod (205) is fixedly connected to one side of the push-pull plate (201), a straight groove plate (208) is provided on one side of the connecting rod (205), and a limit pin (209) is fixedly connected to one side of the wheel (207) at a non-center position; The plug-in mechanism (3) includes a leveling block (301) fixedly installed on the outside of the output end of the motor (206). A plug-in rod (302) is symmetrically arranged inside the leveling block (301). A plug-in block (306) adapted to the output end of the motor (206) is symmetrically arranged on one side of the wheel (207). An L-shaped pressure block (305) is arranged inside the leveling block (301). A spring (304) is fixedly connected to one side of the L-shaped pressure block (305).

2. The device for quantitatively proportioning fructooligosaccharide processing saccharifying enzymes according to claim 1, characterized in that: The storage box (1) has a square hole on one side that is adapted to the push-pull plate (201). The push-pull plate (201) is slidably connected inside the square hole, and the limiting pin (209) is slidably connected inside the straight groove plate (208).

3. The device for quantitatively proportioning fructooligosaccharide processing saccharifying enzymes according to claim 2, characterized in that: An L-shaped plate (204) is fixedly installed at the bottom of the storage box (1), a motor (206) is provided at the top of the L-shaped plate (204), a wheel (207) is fixedly installed at the output end of the motor (206), a guide plate (203) is fixedly installed on the inner surface of the storage box (1), and a discharge trough (202) is fixedly connected to the bottom of the storage box (1).

4. The device for quantitatively proportioning fructooligosaccharide processing saccharifying enzymes according to claim 3, characterized in that: The top of the leveling block (301), the motor (206), and the plug-in block (306) are symmetrically provided with insertion holes adapted to the plug-in rod (302). The plug-in rod (302) is inserted into the insertion hole in sequence. The output end of the motor (206) is provided with a slot adapted to the plug-in block (306). The plug-in block (306) is movably engaged in the slot.

5. The device for quantitatively proportioning fructooligosaccharide processing saccharifying enzymes according to claim 4, characterized in that: The top of the leveling block (301) is provided with a groove that is adapted to the L-shaped pressure block (305). The L-shaped pressure block (305) is slidably connected inside the groove. The top of the plug rod (302) is fixedly installed with a limiting plate (303), and the L-shaped pressure block (305) is located on the top of the limiting plate (303).

6. The device for quantitatively proportioning fructooligosaccharide processing saccharifying enzymes according to claim 5, characterized in that: A servo telescopic cylinder (307) is fixedly installed at the bottom of the L-shaped plate (204). A top block (308) is fixedly connected to the output end of the servo telescopic cylinder (307). A sliding hole adapted to the top block (308) is opened at the top of the L-shaped plate (204). The top block (308) is slidably connected inside the sliding hole. The top of the top block (308) is fixedly connected to the bottom of the motor (206).