A pulverizing device for extracting protein peptides

By introducing intermittent feeding and a multi-stage pulverizing mechanism into the protein peptide extraction device, the problems of feeding blockage and incomplete pulverization in the pulverizing device are solved, and efficient and uniform pulverization of materials is achieved.

CN224443159UActive Publication Date: 2026-07-03YANTAI YOUXIANG BIOTECHNOLOGY CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
YANTAI YOUXIANG BIOTECHNOLOGY CO LTD
Filing Date
2025-07-19
Publication Date
2026-07-03

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Abstract

This utility model discloses a pulverizing device for protein peptide extraction, comprising: a crushing chamber with a feed inlet installed on top; the crushing chamber is equipped with a multi-stage pulverizing mechanism to improve the material crushing effect, wherein the multi-stage pulverizing mechanism includes a crushing rod frame, a pulley, a connecting belt, and a second motor. The crushing rod frame is rotatably mounted inside the upper part of the crushing chamber, and a pulley is fixedly installed on the rear exterior of the crushing rod frame, with a connecting belt slidably mounted on the outer side of the pulley. This pulverizing device for protein peptide extraction, by setting an intermittent feeding mechanism, allows for multiple small-batch feedings of material, reducing material feeding blockage. It also incorporates an anti-blocking mechanism to prevent blockage during the multi-stage pulverizing process. Furthermore, the multi-stage pulverizing mechanism allows for multiple pulverizations of the material, significantly improving the pulverizing effect.
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Description

Technical Field

[0001] This utility model relates to the field of protein peptide extraction technology, specifically a pulverizing device for protein peptide extraction. Background Technology

[0002] Protein peptide powder products are a type of small molecule protein raw material made from traditional protein raw materials, such as chicken and duck meat, through processes such as targeted enzymatic hydrolysis, sterilization, and spray drying. It has the characteristics of easy digestion and absorption, rich in functional peptides, and uniform and fine texture. It can be used as a stable protein raw material in various pet foods to increase the added value of the products. The digestibility and absorption rate of the products can reach about 100%. Currently, there are various types of pulverizing devices for protein peptide extraction on the market, but there are still some shortcomings.

[0003] For example, Chinese utility model patent CN218796407U discloses a pulverizing device for extracting bovine bone collagen peptides. The device uses two gears b to drive two primary pulverizing rollers to rotate in opposite directions, thereby initially pulverizing the bovine bone. Two gears c drive two secondary grinding mills to rotate in opposite directions, further pulverizing the bovine bone. The pulverizing mechanism further pulverizes the bovine bone inside the lower shell. Through the above multi-stage pulverization, the fineness and thoroughness of the bovine bone pulverization are fully improved.

[0004] The existing technology has the following technical problems: the current crushing device directly pours the raw material to be crushed into the crushing box, which is prone to blockage. At the same time, the material is not crushed thoroughly, which will affect the final crushing effect. Therefore, we propose a crushing device for protein peptide extraction to solve the problems mentioned above. Utility Model Content

[0005] The purpose of this utility model is to provide a pulverizing device for protein peptide extraction, in order to solve the problems mentioned above in the background art. In general, when the pulverizing device is used, the raw material to be pulverized is directly poured into the pulverizing box, which is prone to blockage. At the same time, the material is not pulverized thoroughly, which will affect the final material pulverization effect.

[0006] To achieve the above objectives, this utility model provides the following technical solution: a pulverizing device for extracting protein peptides, comprising:

[0007] A crushing box, wherein a feed inlet is installed on the top of the crushing box;

[0008] Also includes:

[0009] The crushing box is equipped with a multi-stage crushing mechanism to improve the crushing effect of materials. The multi-stage crushing mechanism includes a crushing rod frame, a pulley, a connecting belt, and a second motor. The crushing rod frame is rotatably installed inside the upper part of the crushing box, and a pulley is fixedly installed on the rear external side of the crushing rod frame. A connecting belt is slidably installed on the outer side of the pulley, and a second motor is connected to the left front end of the crushing rod frame.

[0010] The feed inlet is equipped with a sliding plate, and the outside of the sliding plate is equipped with an intermittent feeding mechanism to prevent material blockage.

[0011] Preferably, the multi-stage crushing mechanism inside the crushing box further includes a crushing roller and a second gear. The crushing roller is symmetrically rotated and installed on the lower part of the inside of the crushing box, and the second gear is fixedly installed on the rear side of the crushing roller. A second motor is connected to the left front of the second gear.

[0012] Preferably, the intermittent feeding mechanism provided on the outer side of the moving plate includes a first rack, a second rack, a first gear, and a first motor. The first rack is fixedly installed on the outer front side of the moving plate, and the second rack is fixedly installed on the outer rear side of the first rack. The first gear is meshed between the first rack and the second rack, and the first motor is connected below the first gear.

[0013] Preferably, a screen plate is installed on the upper part of the crushing box, and the screen plate is located below the crushing rod frame, and the screen plate has an array of discharge holes inside.

[0014] Preferably, springs are symmetrically fixedly connected to the lower part of the sieve plate, and protective hoses are provided on the outer side of the springs.

[0015] Preferably, an inclined plate is fixedly connected to the lower part of the spring, and a crushing box is fixedly connected to the outer side of the inclined plate, and the inclined plate is arranged in a sloping manner inside the crushing box.

[0016] Preferably, a baffle is symmetrically slidably arranged on the lower middle part of the crushing box, and an electric telescopic rod is installed on the outer side of the baffle, and the electric telescopic rod is symmetrically installed on the lower inside of the crushing box.

[0017] Compared with the prior art, the beneficial effects of this utility model are: the pulverizing device for protein peptide extraction, by setting an intermittent feeding mechanism, enables the material to be fed in small quantities multiple times, which can reduce the occurrence of material feeding blockage. At the same time, an anti-blocking mechanism is set to avoid the material from being blocked during multi-stage pulverization. In addition, the multi-stage pulverizing mechanism can pulverize the material multiple times, which can greatly improve the pulverization effect of the material.

[0018] 1. It is equipped with a feed inlet and a moving plate. The feed inlet is installed on the top of the crushing box, and the moving plate is set inside the feed inlet. The moving plate can move inside the feed inlet and outward. When the moving plate moves outward, the material can be fed into the crushing box from the inside of the feed inlet. When the moving plate moves inward, the material will stop entering the crushing box, so that the material can be fed in small amounts multiple times.

[0019] 2. It is equipped with crushing rods and crushing rollers. The crushing rods are symmetrically installed on the left and right sides inside the crushing box. The crushing rods can break up and crush the material entering the crushing box for the first time. The crushed material will fall to the bottom of the crushing box. The crushing rollers are symmetrically installed on the left and right sides inside the bottom of the crushing box. The crushing rollers can crush the material for the second time. Multiple crushing can improve the crushing effect of the material.

[0020] 3. Equipped with a screen plate and a discharge hole, the screen plate is set between the crushing rod frame and the crushing roller. The discharge hole is arrayed inside the screen plate, which can uniformly convey the crushed material through the screen plate downward. Springs are also installed under the screen plate, which can make the screen plate bounce inside the crushing box, effectively preventing the material from being blocked inside the discharge hole during discharge. Attached Figure Description

[0021] Figure 1 This is a perspective structural diagram of the present invention;

[0022] Figure 2 This is a perspective view of the connection structure of the crushing box, baffle and electric telescopic rod of this utility model;

[0023] Figure 3 This is a perspective cross-sectional structural diagram of the present invention;

[0024] Figure 4 This is a perspective view of the connection structure of the crushing box, crushing rod frame and screen plate of this utility model;

[0025] Figure 5 This is a perspective view of the connection structure of the movable plate, the first rack, and the second rack of this utility model.

[0026] Figure 6 This is a perspective view of the sieve plate, discharge hole, and spring connection structure of this utility model.

[0027] In the diagram: 1. Crushing box; 2. Feed inlet; 3. Moving plate; 4. First rack; 5. Second rack; 6. First gear; 7. First motor; 8. Crushing rod frame; 9. Pulley; 10. Connecting belt; 11. Second motor; 12. Screen plate; 13. Discharge hole; 14. Spring; 15. Protective hose; 16. Crushing roller; 17. Second gear; 18. Baffle; 19. Electric telescopic rod; 20. Inclined plate. Detailed Implementation

[0028] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the protection scope of the present utility model.

[0029] Please see Figures 1-6 This utility model provides a technical solution:

[0030] To address the problems existing in the prior art, this embodiment provides the following technical solution: a pulverizing device for protein peptide extraction, comprising a pulverizing chamber 1; an intermittent feeding mechanism located on the outside of the moving plate 3, allowing material to enter the pulverizing chamber 1 in small quantities multiple times for pulverization, effectively preventing clogging; an anti-clogging mechanism located inside the pulverizing chamber 1, preventing clogging during multi-stage pulverization and feeding, thus enabling the device to effectively pulverize the material; and a multi-stage pulverizing mechanism located inside the pulverizing chamber 1, enabling multi-stage pulverization of the material, thereby improving the pulverization effect.

[0031] like Figure 1 , Figure 3 and Figure 5As shown, a feed inlet 2 is installed above the crushing box 1. A movable plate 3 is symmetrically arranged inside the feed inlet 2. A first rack 4 is fixedly installed on the front side of the movable plate 3, and a second rack 5 is fixedly installed on the rear side of the movable plate 3. A first gear 6 is meshed between the first rack 4 and the second rack 5. When the first motor 7 connected below the first gear 6 is turned on, the first gear 6 rotates, causing the meshed first rack 4 and the second rack 5 to move in opposite directions. This movement of the first rack 4 and the second rack 5 causes the movable plate 3 to move inward and outward inside the feed inlet 2. When the movable plate 3 moves outward, the outlet at the lower center of the feed inlet 2 can be opened, allowing material to be fed into the crushing box 1 from inside the feed inlet 2. When the movable plate 3 moves inward, material entry into the crushing box 1 is stopped, allowing material to be fed into the crushing box 1 in small, repeated batches.

[0032] like Figure 2 , Figure 3 and Figure 4 As shown, after the material enters the crushing box 1, a crushing rod frame 8 is symmetrically rotated on the upper left and right sides of the crushing box 1. A pulley 9 is fixedly connected to the front of the crushing rod frame 8. A connecting belt 10 is slidably set on the outside of the pulley 9. The second motor 11 connected to the front left side of the crushing rod frame 8 can be turned on, which will make the pulley 9 rotate. The connecting belt 10 set on the outside of the pulley 9 is in the shape of "8", which can make the pulley 9 rotate in the opposite direction. At this time, the crushing rod frame 8 can break up and crush the material entering the crushing box 1 for the first time inside the crushing box 1.

[0033] like Figure 3 , Figure 4 and Figure 6 As shown, a screen plate 12 is installed below the crushing rod frame 8. The screen plate 12 has an array of discharge holes 13 inside, so that the material crushed by the crushing rod frame 8 can be output evenly downwards. Springs 14 are symmetrically arranged on the left and right sides below the screen plate 12. An inclined plate 20 is fixedly connected to the bottom of the springs 14. A protective hose 15 is installed on the outside of the springs 14 for protection. The springs 14 will bounce according to the weight of the material falling above the screen plate 12, so that the material crushed by the crushing rod frame 8 can fall smoothly down through the discharge holes 13, which can effectively avoid the occurrence of blockage.

[0034] Secondly, the inclined plate 20 fixedly connected below the spring 14 is installed above the crushing roller 16 in a sloping manner. The material output from the feed hole 13 can slide down the slope of the inclined plate 20 to the middle. The material can enter the middle of the crushing roller 16, which is symmetrically arranged on the left and right sides inside the crushing box 1. The second gear 17 is fixedly installed on the rear side of the crushing roller 16. The second gear 17 is symmetrically meshed on the front side of the crushing box 1. When the second motor 11 installed on the left front of the crushing roller 16 is turned on, the second gear 17 can rotate. The second gear 17 installed on the rear side of the crushing roller 16 will rotate inward and mesh, so that the crushing roller 16 also rotates inward inside the crushing box 1, thus crushing the material a second time.

[0035] After the material is crushed, baffles 18 are symmetrically installed on the left and right sides above the lower output port of the crushing box 1. The electric telescopic rod 19 fixedly connected to the outside of the baffle 18 can be opened. The output end of the electric telescopic rod 19 can pull the baffle 18 to move outward, that is, the baffle 18 moves and opens, which facilitates the feeding of materials.

[0036] The working principle of the pulverizing device for extracting protein peptides is as follows: A feed inlet 2 is set above the crushing chamber 1. The moving plate 3 inside the feed inlet 2 can move inward and outward, which facilitates the feeding of materials in small quantities multiple times and avoids material blockage. At the same time, a multi-stage crushing mechanism is set inside the crushing chamber 1, which can improve the crushing effect of materials by crushing them multiple times. In addition, uniform vibration feeding can be performed during the crushing process, which can effectively avoid material blockage during the crushing process.

[0037] Contents not described in detail in this specification are common knowledge to those skilled in the art. All standard parts used in this invention can be purchased commercially, and irregularly shaped parts can be custom-made according to the description and drawings. The specific connection methods for each part all employ conventional methods such as bolts, rivets, and welding, which are already mature in the prior art. The machinery, parts, and equipment all use conventional models from the prior art, and the circuit connections also employ conventional connection methods from the prior art, which will not be detailed here.

[0038] Although the present invention has been described in detail with reference to the foregoing embodiments, those skilled in the art can still modify the technical solutions described in the foregoing embodiments or make equivalent substitutions for some of the technical features. Any modifications, equivalent substitutions, improvements, etc., made within the spirit and principles of the present invention should be included within the protection scope of the present invention.

Claims

1. A pulverizing device for extracting protein peptides, comprising: A crushing box (1) is provided with a feed inlet (2) on its top. Its characteristic is that it further includes: The crushing box (1) is equipped with a multi-stage crushing mechanism to improve the crushing effect of materials. The multi-stage crushing mechanism includes a crushing rod frame (8), a pulley (9), a connecting belt (10), and a second motor (11). The crushing rod frame (8) is rotatably installed inside the crushing box (1) and the pulley (9) is fixedly installed on the rear side of the crushing rod frame (8). The connecting belt (10) is slidably installed on the outer side of the pulley (9). The second motor (11) is connected to the left front end of the crushing rod frame (8). The feed inlet (2) is slidably provided with a moving plate (3), and the outside of the moving plate (3) is provided with an intermittent feeding mechanism to avoid material blockage.

2. The crushing device for extracting protein peptide according to claim 1, characterized in that: The multi-stage crushing mechanism inside the crushing box (1) also includes a crushing roller (16) and a second gear (17). The crushing roller (16) is symmetrically rotated and installed on the lower part of the inside of the crushing box (1). The second gear (17) is fixedly installed on the rear side of the crushing roller (16), and a second motor (11) is connected to the left front of the second gear (17).

3. The crushing device for extracting protein peptide according to claim 1, characterized in that: The intermittent feeding mechanism provided on the outer side of the moving plate (3) includes a first rack (4), a second rack (5), a first gear (6), and a first motor (7). The first rack (4) is fixedly installed on the outer front side of the moving plate (3), and the second rack (5) is fixedly installed on the outer rear side of the first rack (4). The first gear (6) is meshed between the first rack (4) and the second rack (5), and the first motor (7) is connected below the first gear (6).

4. The crushing device for extracting protein peptide according to claim 1, characterized in that: A screen plate (12) is installed on the upper part of the crushing box (1), and the screen plate (12) is located below the crushing rod frame (8). The screen plate (12) has an array of discharge holes (13) inside.

5. The protein peptide extraction pulverizing device according to claim 4, characterized in that: Springs (14) are fixedly connected symmetrically to the bottom of the sieve plate (12), and a protective hose (15) is provided on the outside of the spring (14).

6. The protein peptide extraction pulverizing device according to claim 5, characterized in that: A ramp (20) is fixedly connected to the lower part of the spring (14), and a crushing box (1) is fixedly connected to the outer side of the ramp (20). The ramp (20) is set in a sloping manner inside the crushing box (1).

7. The protein peptide extraction pulverizing device according to claim 6, characterized in that: A baffle (18) is symmetrically slidably arranged on the lower middle part of the crushing box (1), and an electric telescopic rod (19) is installed on the outer side of the baffle (18). The electric telescopic rod (19) is symmetrically installed on the lower inside of the crushing box (1).