High-viscosity essence sound wave standing wave field homogenization equipment

By designing a high-viscosity fragrance acoustic standing wave field homogenizing device with a wall scraping mechanism and a homogenizing mechanism, the problem of fragrance adhering to the inner wall of the homogenizing box was solved, achieving complete fragrance discharge and homogenization effect.

CN224321323UActive Publication Date: 2026-06-05SHENZHEN HUAICHI TECH CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
SHENZHEN HUAICHI TECH CO LTD
Filing Date
2025-04-28
Publication Date
2026-06-05

AI Technical Summary

Technical Problem

High-viscosity fragrances tend to adhere to the inner wall of the homogenization chamber after homogenization, resulting in resource waste and reduced applicability.

Method used

A high-viscosity fragrance acoustic standing wave field homogenizing device was designed, comprising a wall scraping mechanism and a homogenizing mechanism. The wall scraping mechanism scrapes off the fragrance adhering to the inner wall through a scraping frame, while the homogenizing mechanism achieves homogenization and dispersion of the high-viscosity fragrance through an acoustic standing wave field.

Benefits of technology

This achieves complete removal of high-viscosity fragrances, avoids resource waste, and improves the applicability of the equipment.

✦ Generated by Eureka AI based on patent content.

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  • Figure CN224321323U_ABST
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Patent Text Reader

Abstract

The utility model belongs to high viscosity essence field especially, it is a kind of high viscosity essence sound wave standing wave field homogenization equipment, to the high viscosity essence of existing high viscosity essence after homogenization, due to the high viscosity essence will be attached on the inner wall of homogenization box in large quantities, and not conducive to completely discharge, leading to the adhered essence will cause resource waste, reduced the problem of suitable effect, present and propose the following scheme, including bottom frame, the inside of bottom frame is provided with homogenization box, the top of homogenization box is connected with sealing cover by hinge rotation, wall scraping mechanism, wall scraping mechanism sets up at the top of bottom frame for the high viscosity essence adhered to the inner wall of homogenization box is scraped clean. The utility model in use, high viscosity essence after homogenization, it is favorable to scrape clean the high viscosity essence adhered on the inner wall, prevent essence residual influence subsequent processing or cause equipment blockage etc. problem, reaches the purpose of completely discharging, avoids the adhered essence will cause resource waste, improves the suitable effect.
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Description

Technical Field

[0001] This utility model relates to the field of high viscosity fragrance technology, and in particular to a high viscosity fragrance acoustic standing wave field homogenization device. Background Technology

[0002] The high-viscosity fragrance ultrasonic standing wave field homogenizer is an advanced technology that uses ultrasonic standing wave fields to efficiently homogenize, disperse, and stabilize high-viscosity fragrances (such as essential oils and resin fragrances). Its core principle is to use the standing wave field generated by ultrasound to form periodic high-pressure / low-pressure regions in the liquid, thereby achieving shearing, cavitation, and mixing at the microscale.

[0003] In existing methods, when high-viscosity fragrances are discharged after homogenization, a large amount of the high-viscosity fragrance will adhere to the inner wall of the homogenization box, which is not conducive to complete discharge. This results in the waste of resources and reduces the applicability of the fragrance.

[0004] To address the aforementioned issues, this utility model proposes a high-viscosity fragrance acoustic standing wave field homogenization device. Utility Model Content

[0005] This invention provides a high-viscosity fragrance acoustic standing wave field homogenization device, which solves the problem in the prior art where, after homogenization, a large amount of high-viscosity fragrance adheres to the inner wall of the homogenization box, which is not conducive to complete discharge, resulting in resource waste and reduced applicability.

[0006] This utility model provides the following technical solution:

[0007] A high-viscosity fragrance acoustic standing wave field homogenizing device, comprising:

[0008] The bottom frame contains a homogenizing chamber, and the top of the homogenizing chamber is rotatably connected to a sealing cover via a hinge.

[0009] The wall scraping mechanism is located at the top of the bottom frame and is used to scrape off the high-viscosity fragrance adhering to the inner wall of the homogenizing box.

[0010] The homogenizing mechanism is installed on the homogenizing chamber and is used to homogenize the high-viscosity fragrance inside the homogenizing chamber.

[0011] In one possible design, the wall scraping mechanism includes a top frame, a threaded rod, a mounting plate, a scraping frame, a limiting telescopic rod, an insert block, and a slot. The top frame is rotatably connected to the top of the bottom frame via a rotating shaft. The threaded rod is threadedly connected to the inside of the top frame. The mounting plate is rotatably connected to the bottom end of the threaded rod via a rotating shaft. The scraping frame is fixedly installed on the bottom side of the mounting plate and is used to scrape off the high-viscosity fragrance adhering to the inner wall of the homogenizing chamber.

[0012] In one possible design, two limiting telescopic rods are fixedly installed between the bottom inner wall of the top frame and the top side of the mounting plate. Both of the two inserts are welded to the bottom side of the top frame, and both of the slots are opened on the top side of the bottom frame for positioning and insertion of the inserts.

[0013] In one possible design, the homogenizing mechanism includes a hummingbird acoustic resonant motor, a support telescopic rod, and a spring. The hummingbird acoustic resonant motor is fixedly installed on the bottom side of the homogenizing box by bolts. Each of the support telescopic rods and springs is fixedly disposed between the bottom side of the homogenizing box and the inner wall of the bottom side of the bottom frame. The spring is sleeved on the outer wall of the support telescopic rod.

[0014] In one possible design, the bottom side of the homogenizing tank is connected to two discharge pipes, and each discharge pipe is equipped with a solenoid valve on its outer wall. The bottom of the base frame is provided with a receiving frame corresponding to the two discharge pipes.

[0015] In one possible design, a connecting plate is welded to one side of both the sealing cover and the homogenizing box, and the two connecting plates are connected and fixed together by fasteners, each set of fasteners including a bolt and a nut.

[0016] In one possible design, a sealing gasket is glued to the bottom side of the sealing cover, and a seal is provided on the top side of the homogenizing chamber for the sealing gasket to be snapped into place.

[0017] In this application, during use, the high-viscosity fragrance to be processed is first added to the homogenizing chamber. Then, a sealing cap is placed on top of the homogenizing chamber. Connecting plates are welded to both the sealing cap and one side of the homogenizing chamber. By passing bolts through the two connecting plates and tightening them with nuts, a tight connection between the sealing cap and the homogenizing chamber is achieved. Simultaneously, a sealing gasket glued to the bottom of the sealing cap is locked into a sealing groove on the top side of the homogenizing chamber, further enhancing the sealing effect and preventing fragrance leakage during homogenization. When the equipment starts working, the hummingbird acoustic resonance motor, fixedly installed on the bottom side of the homogenizing chamber, is activated by an external power supply and control circuit. The hummingbird acoustic resonance motor generates sound waves of a specific frequency during operation. These sound waves propagate within the homogenizing chamber and are... Due to the boundary conditions and internal spatial structure of the homogenizing chamber, sound waves will form a standing wave field inside the chamber. Different positions in the standing wave field have different sound pressure and sound intensity distributions, causing the high-viscosity flavoring to vibrate and stir violently under the action of sound waves. Under the action of the sound wave standing wave field, the particles or molecules in the high-viscosity flavoring are constantly impacted and stirred by the sound wave energy, thereby breaking the original aggregation state and achieving uniform dispersion, thus achieving the purpose of homogenization. At the same time, the support telescopic rod and spring set on the bottom side of the homogenizing chamber play a supporting and buffering role. The support telescopic rod provides support when the homogenizing chamber moves up and down due to sound wave vibration, while the spring absorbs part of the vibration energy through its own elastic deformation, ensuring the stability of the homogenizing chamber and the normal operation of the equipment as a whole.

[0018] After homogenization is completed, the solenoid valves on the two discharge pipes connected to the bottom of the homogenizing chamber are opened via the control circuit. Once the solenoid valves open, the high-viscosity flavoring in the homogenizing chamber is discharged through the discharge pipes. The receiving frames at the bottom of the frame, corresponding to the two discharge pipes, are used to receive the discharged flavoring for convenient subsequent processing and collection. When scraping is required, the top frame is rotated around the pivot to a position perpendicular to the bottom frame. At this time, the two inserts on the bottom side of the top frame are positioned and inserted into the two slots on the top side of the bottom frame, thus fixing the top frame in place and ensuring the stability of the scraping mechanism during operation. Then, by rotating the threaded rod, which is threadedly connected to the top frame... Furthermore, the mounting plate is rotatably connected to the bottom end of the threaded screw rod via a rotating shaft. As the threaded screw rod rotates, the mounting plate moves up and down under the limiting action of the limiting telescopic rod. The limiting telescopic rod ensures that the mounting plate can only move in a straight line up and down, preventing the mounting plate from shifting. As the mounting plate moves up and down, the scraper frame fixedly installed on the bottom side of the mounting plate also moves up and down accordingly. During the movement, the scraper frame contacts the inner wall of the homogenizing box, which helps to cleanly remove the high-viscosity fragrance adhering to the inner wall, preventing fragrance residue from affecting subsequent processing or causing equipment blockage, thus achieving the purpose of complete discharge, avoiding resource waste caused by the adhering fragrance, and improving the application effect.

[0019] In this utility model, the high-viscosity fragrance acoustic standing wave field homogenizing device uses a wall scraping mechanism. During the movement of the scraping frame, it comes into contact with the inner wall of the homogenizing box, which helps to clean the high-viscosity fragrance adhering to the inner wall and prevent fragrance residue from affecting subsequent processing or causing equipment blockage.

[0020] In this utility model, the high-viscosity flavoring acoustic standing wave field homogenizing device can cause the high-viscosity flavoring to vibrate and stir violently under the action of sound waves through the homogenizing mechanism. Under the action of the acoustic standing wave field, the particles or molecules in the high-viscosity flavoring are continuously impacted and stirred by the sound wave energy, thereby breaking the original aggregation state, achieving uniform dispersion, and achieving the purpose of homogenization processing.

[0021] In this invention, when the high-viscosity fragrance is discharged after homogenization, it is beneficial to scrape off the high-viscosity fragrance adhering to the inner wall, preventing fragrance residue from affecting subsequent processing or causing equipment blockage, thus achieving the purpose of complete discharge, avoiding resource waste caused by the adhering fragrance, and improving the application effect. Attached Figure Description

[0022] Figure 1 This is a schematic diagram of the main structure of a high-viscosity fragrance acoustic standing wave field homogenizing device provided in an embodiment of the present invention;

[0023] Figure 2A schematic diagram of the top frame of a high-viscosity fragrance acoustic standing wave field homogenizing device in the open state, provided for an embodiment of this utility model;

[0024] Figure 3 This is one of the schematic diagrams of the open state of the sealing cover of a high-viscosity fragrance acoustic standing wave field homogenizing device provided in an embodiment of the present invention;

[0025] Figure 4 This is the second schematic diagram of the open state of the sealing cover of a high-viscosity fragrance acoustic standing wave field homogenizing device provided in this embodiment of the present invention.

[0026] Figure label:

[0027] 1. Base frame; 2. Homogenizing chamber; 3. Hummingbird resonance motor; 4. Support telescopic rod; 5. Spring; 6. Sealing cover; 7. Connecting plate; 8. Fastener; 9. Discharge pipe; 10. Solenoid valve; 11. Sealing gasket; 12. Top frame; 13. Threaded swivel rod; 14. Mounting plate; 15. Scraper frame; 16. Limiting telescopic rod; 17. Insert block; 18. Slot; 19. Receiving frame. 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 of the present utility model. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments.

[0029] Example 1

[0030] The existing problem in the field of high-viscosity fragrances is that when high-viscosity fragrances are discharged after homogenization, a large amount of high-viscosity fragrances will adhere to the inner wall of the homogenization box, which is not conducive to complete discharge. This leads to waste of resources and reduced applicability. To address this problem, this solution designs a homogenization device.

[0031] Please refer to Figures 1-4 A homogenizing device, comprising:

[0032] The bottom frame 1 has a homogenizing chamber 2 inside it. The top of the homogenizing chamber 2 is connected to a sealing cover 6 by a hinge. When the sealing cover 6 is placed on the top of the homogenizing chamber 2, a tight connection between the sealing cover 6 and the homogenizing chamber 2 can be achieved.

[0033] A wall-scraping mechanism, located at the top of the bottom frame 1, is used to cleanly scrape away the high-viscosity fragrance adhering to the inner wall of the homogenizing chamber 2. The wall-scraping mechanism includes a top frame 12, a threaded rotating rod 13, a mounting plate 14, a scraping frame 15, a limiting telescopic rod 16, an insert block 17, and a slot 18. The top frame 12 is rotatably connected to the top of the bottom frame 1 via a rotating shaft. The threaded rotating rod 13 is threadedly connected to the inside of the top frame 12. The mounting plate 14 is rotatably connected to the bottom end of the threaded rotating rod 13 via a rotating shaft. The scraping frame 15 is fixedly installed on the bottom side of the mounting plate 14 and is used to cleanly scrape away the high-viscosity fragrance adhering to the inner wall of the homogenizing chamber 2. As the threaded screw 13 rotates, the mounting plate 14 moves up and down under the limiting action of the limiting telescopic rod 16. The limiting telescopic rod 16 ensures that the mounting plate 14 can only move in a straight line up and down, preventing the mounting plate 14 from shifting. As the mounting plate 14 moves up and down, the scraper frame 15, which is fixedly installed on the bottom side of the mounting plate 14, also moves up and down. During the movement, the scraper frame 15 contacts the inner wall of the homogenizing box 2, which helps to scrape off the high-viscosity fragrance adhering to the inner wall, preventing fragrance residue from affecting subsequent processing or causing equipment blockage, thus achieving the purpose of complete discharge.

[0034] Two limiting telescopic rods 16 are fixedly installed between the bottom inner wall of the top frame 12 and the top side of the mounting plate 14. Two inserts 17 are welded to the bottom side of the top frame 12, and two slots 18 are opened on the top side of the bottom frame 1 for the inserts 17 to be positioned and inserted. When the top frame 12 is rotated around the pivot to a position perpendicular to the bottom frame 1, the two inserts 17 on the bottom side of the top frame 12 will be positioned and inserted into the two slots 18 on the top side of the bottom frame 1, thereby fixing the top frame 12 and ensuring the stability of the scraping mechanism during operation.

[0035] The homogenizing mechanism, installed on the homogenizing chamber 2, is used to homogenize the high-viscosity flavoring inside the homogenizing chamber 2. The homogenizing mechanism includes a hummingbird acoustic resonant motor 3, a support telescopic rod 4, and a spring 5. The hummingbird acoustic resonant motor 3 is fixedly installed on the bottom side of the homogenizing chamber 2 by bolts. During operation, the hummingbird acoustic resonant motor 3 generates sound waves of a specific frequency. The generated sound waves propagate inside the homogenizing chamber 2. Due to the boundary conditions and internal spatial structure of the homogenizing chamber 2, the sound waves will form a standing wave field inside the chamber. Different positions in the standing wave field have different sound pressure and sound intensity distributions, causing the high-viscosity flavoring to vibrate and stir violently under the action of the sound waves. Each support telescopic rod 4 and spring 5 is fixedly installed between the bottom side of the homogenizing box 2 and the bottom inner wall of the bottom frame 1. The spring 5 is sleeved on the outer wall of the support telescopic rod 4. The support telescopic rod 4 and spring 5 installed on the bottom side of the homogenizing box 2 play a supporting and buffering role. The support telescopic rod 4 provides support when the homogenizing box 2 moves up and down due to sound wave vibration, and the spring 5 absorbs part of the vibration energy through its own elastic deformation, ensuring the stability of the homogenizing box 2 and the normal operation of the equipment as a whole.

[0036] The bottom of the homogenizing chamber 2 is connected to two discharge pipes 9. Each discharge pipe 9 is equipped with a solenoid valve 10 on its outer wall. The bottom of the bottom frame 1 is equipped with a receiving frame 19 corresponding to the two discharge pipes 9. The solenoid valves 10 on the two discharge pipes 9 connected to the bottom of the homogenizing chamber 2 are opened by the control circuit. After the solenoid valves 10 are opened, the high-viscosity fragrance in the homogenizing chamber 2 will be discharged through the discharge pipes 9. The receiving frame 19 at the bottom of the bottom frame 1, corresponding to the two discharge pipes 9, is used to receive the discharged fragrance for convenient subsequent processing and collection.

[0037] This application can be used in the field of high-viscosity fragrances, or in other fields applicable to this application.

[0038] The model of the hummingbird acoustic resonant motor 3 is JZO-100-4, and its structure and mechanism will not be described in detail here.

[0039] Example 2

[0040] refer to Figures 1-3 An improvement based on Example 1: a high-viscosity fragrance acoustic standing wave field homogenizing device, which is applied to the field of high-viscosity fragrances;

[0041] Both the sealing cover 6 and the homogenizing box 2 have a connecting plate 7 welded to one side. The two connecting plates 7 are connected and fixed by fasteners 8. Each set of fasteners 8 includes a bolt and a nut. By passing the bolt through the two connecting plates 7 and tightening it with the nut, a tight connection between the sealing cover 6 and the homogenizing box 2 can be achieved.

[0042] A sealing gasket 11 is glued to the bottom side of the sealing cover 6. A sealing groove is provided on the top side of the homogenizing box 2 for the sealing gasket 11 to be sealed and snapped into the sealing groove on the top side of the homogenizing box 2, which further enhances the sealing effect and prevents the fragrance from leaking during the homogenization process.

[0043] However, as is well known to those skilled in the art, the working principle and wiring method of the hummingbird acoustic resonant motor 3 and the solenoid valve 10 are commonplace and are all conventional methods or common knowledge. They will not be described in detail here. Those skilled in the art can make any selections according to their needs or convenience.

[0044] The accompanying drawings in this application are for illustrative purposes only. The dimensions and shapes of the components shown are not actual limitations, but are merely schematic representations. In actual implementation, the components can be reasonably configured and adjusted according to specific needs and actual conditions.

[0045] The above are merely specific embodiments of this utility model, but the protection scope of this utility model is not limited thereto. Any variations or substitutions that can be easily conceived by those skilled in the art within the technical scope disclosed in this utility model should be included within the protection scope of this utility model. In the absence of conflict, the embodiments and features in the embodiments of this utility model can be combined with each other. Therefore, the protection scope of this utility model should be determined by the scope of the claims.

Claims

1. A high-viscosity fragrance acoustic standing wave field homogenization device, characterized in that, include: The bottom frame (1) has a homogenizing box (2) inside it, and the top of the homogenizing box (2) is connected to a sealing cover (6) by a hinge. The wall scraping mechanism is set at the top of the bottom frame (1) to scrape off the high-viscosity fragrance adhering to the inner wall of the homogenizing box (2); The homogenizing mechanism is set on the homogenizing box (2) and is used to homogenize the high viscosity fragrance in the homogenizing box (2).

2. The high-viscosity fragrance acoustic standing wave field homogenizing device according to claim 1, characterized in that, The wall scraping mechanism includes a top frame (12), a threaded swivel rod (13), a mounting plate (14), a scraping frame (15), a limiting telescopic rod (16), an insert (17), and a slot (18). The top frame (12) is rotatably connected to the top of the bottom frame (1) via a rotating shaft. The threaded swivel rod (13) is threadedly connected to the inside of the top frame (12). The mounting plate (14) is rotatably connected to the bottom end of the threaded swivel rod (13) via a rotating shaft. The scraping frame (15) is fixedly installed on the bottom side of the mounting plate (14) and is used to scrape off the high-viscosity fragrance adhering to the inner wall of the homogenizing box (2).

3. The high-viscosity fragrance acoustic standing wave field homogenizing device according to claim 2, characterized in that, Two limiting telescopic rods (16) are fixedly installed between the bottom inner wall of the top frame (12) and the top side of the mounting plate (14). The two inserts (17) are welded to the bottom side of the top frame (12), and the two slots (18) are opened on the top side of the bottom frame (1) for positioning and insertion of the inserts (17).

4. The high-viscosity fragrance acoustic standing wave field homogenizing device according to claim 1, characterized in that, The homogenization mechanism includes a hummingbird acoustic resonance motor (3), a support telescopic rod (4), and a spring (5). The hummingbird acoustic resonance motor (3) is fixedly installed on the bottom side of the homogenization box (2) by bolts. Each support telescopic rod (4) and spring (5) is fixedly set between the bottom side of the homogenization box (2) and the bottom inner wall of the bottom frame (1). The spring (5) is sleeved on the outer wall of the support telescopic rod (4).

5. The high-viscosity fragrance acoustic standing wave field homogenizing device according to claim 4, characterized in that, The bottom side of the homogenizing box (2) is connected to two discharge pipes (9), and each discharge pipe (9) is provided with a solenoid valve (10) on its outer wall. The bottom of the bottom frame (1) is provided with a receiving frame (19) corresponding to the two discharge pipes (9).

6. The high-viscosity fragrance acoustic standing wave field homogenizing device according to claim 1, characterized in that, The sealing cover (6) and the homogenizing box (2) are each welded with a connecting plate (7) on one side. The two connecting plates (7) are connected and fixed by fasteners (8). Each set of fasteners (8) includes a bolt and a nut.

7. The high-viscosity fragrance acoustic standing wave field homogenizing device according to claim 6, characterized in that, The bottom side of the sealing cover (6) is glued with a sealing gasket (11), and the top side of the homogenizing box (2) is provided with a sealing groove for the sealing gasket (11) to be sealed and snapped in place.