A bath salt molten salt apparatus
By combining the material equalization rack, stirring rod, and electromagnetic heating ring with the crushing components, the problems of uneven feeding and incomplete crushing in traditional bath salt melting equipment are solved, achieving uniform distribution and efficient crushing of bath salt, thus improving melting efficiency and product quality.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- CHUNAN QIANDAO LAKE CAPITAL LUXURIANT COMMODITY CO LTD
- Filing Date
- 2025-06-12
- Publication Date
- 2026-06-23
AI Technical Summary
Traditional bath salt melting equipment suffers from uneven feed distribution due to its single feeding method and excessively large particles due to its single crushing method, which affects the efficiency and quality of the melting salt.
The material distribution frame, stirring rod, and electromagnetic heating ring are combined with the crushing components, including the crushing frustum and crushing wall. Irregular movement is achieved through the eccentric shaft, which improves the control of material distribution and crushing effect.
This method achieves uniform distribution and efficient pulverization of bath salts within the molten salt cylinder, thereby improving molten salt efficiency and product quality.
Smart Images

Figure CN224388640U_ABST
Abstract
Description
Technical Field
[0001] This utility model belongs to the technical field of molten salt equipment, and more specifically, it relates to a bath salt molten salt equipment. Background Technology
[0002] In the fields of personal care and spa wellness, bath salts are a commonly used health and beauty product, widely applied in various bathing scenarios to help users relax and nourish their skin during bathing. However, bath salts on the market often suffer from uneven particle size and numerous impurities. Without pretreatment and molten salt processing, bath salts are prone to incomplete dissolution during use, affecting their effectiveness and negatively impacting the user experience. To avoid these problems, bath salt molten salt equipment is used. However, traditional devices are typically simple cylindrical structures with a single feeding method, unable to effectively control the distribution of bath salts entering the molten salt cylinder. This results in uneven distribution of bath salts within the cylinder, with some areas having excessive salt accumulation and others sparse, affecting the uniformity of the molten salt, reducing molten salt efficiency, and ultimately impacting product quality. Furthermore, traditional devices lack a simplistic pulverization method; without sufficient and effective pulverization, bath salt particles can become too large, making it difficult to dissolve quickly and completely during the molten salt process, negatively affecting the speed and quality of the molten salt and reducing the pretreatment capabilities of traditional devices before molten salt processing. Utility Model Content
[0003] To address the aforementioned technical problems, this utility model provides a bath salt melting equipment to solve the technical issues in the prior art, such as uneven distribution of bath salt in the melting salt cylinder due to the single feeding method of traditional devices, and excessively large bath salt particles due to the single crushing method, which reduces the pretreatment capacity before melting salt.
[0004] The purpose and effect of this utility model's bath salt melting equipment are achieved by the following specific technical means:
[0005] A bath salt melting device includes a molten salt cylinder and a crushing cylinder. The crushing cylinder is disposed above the molten salt cylinder. A first feed inlet is provided at the top of the molten salt cylinder. A material leveling frame is detachably connected to the bottom of the first feed inlet. A limiting frame is provided below the material leveling frame. A base is provided below the limiting frame. A stirring rod is provided between the base and the limiting frame. A discharge port is integrally formed on one side of the base. An electromagnetic heating ring is provided inside the molten salt cylinder. A crushing component for crushing bath salt is provided inside the crushing cylinder.
[0006] According to a preferred embodiment, the crushing assembly includes a mounting cylinder located below the crushing cylinder, and a first motor and a commutator are respectively disposed inside the mounting cylinder.
[0007] According to a preferred embodiment, the first motor shaft end is disposed inside the commutator, and a crushing frustum is disposed above the commutator, the crushing frustum being connected to the commutator shaft end via an eccentric shaft.
[0008] According to a preferred embodiment, a crushing wall is provided inside the crushing cylinder, the crushing frustum is located inside the crushing wall, and a second feed inlet is detachably connected to the top of the crushing wall.
[0009] According to a preferred embodiment, a connecting frame is provided between the mounting cylinder and the molten salt cylinder, and the bottom of the connecting frame is connected to the first feed port.
[0010] According to a preferred embodiment, the top of the connecting frame is connected to the mounting cylinder via a discharge funnel, and the bottom of the discharge funnel is connected to the first inlet.
[0011] According to a preferred embodiment, a second motor is detachably connected to the bottom of the base, the shaft of the second motor passes through the base and is connected to the stirring rod via a coupling, and multiple sets of supports are provided around the base.
[0012] Compared with the prior art, the present invention has the following beneficial effects:
[0013] 1. This utility model, through the setting of a uniform feeding rack, enables the user to initially disperse the bath salt entering the molten salt cylinder, thereby improving the device's control over the distribution of bath salt feed. After the bath salt enters the molten salt cylinder, the user can use the stirring rod and electromagnetic heating ring to stir and heat the bath salt to melt it, enabling the user to obtain a more uniform molten salt effect, improving the device's molten salt efficiency and the quality of the final product.
[0014] 2. When using this device, the user can crush the bath salts through the crushing disc and crushing wall, allowing the user to break larger bath salt particles into smaller particles, thus improving the device's crushing ability for bath salts. Then, the eccentric shaft enables the crushing disc to generate an irregular motion trajectory, increasing the contact and friction with the bath salts, crushing the bath salts more effectively, bringing the user a finer crushing effect, and improving the device's pretreatment capability for bath salts before melting. Attached Figure Description
[0015] Figure 1 This is a schematic diagram of the assembled structure of this utility model;
[0016] Figure 2 This is a schematic diagram of the exploded structure of this utility model;
[0017] Figure 3 This is a front view structural diagram of the present invention;
[0018] Figure 4 This is a cross-sectional structural diagram of the present invention.
[0019] In the diagram, the correspondence between component names and drawing numbers is as follows:
[0020] 11. Molten salt cylinder; 12. Crushing cylinder; 13. First feed inlet; 14. Blending rack; 15. Limiting rack; 16. Base; 17. Stirring rod; 18. Discharge port; 19. Electromagnetic heating ring; 21. Mounting cylinder; 22. First motor; 23. Commutator; 24. Crushing frustum; 25. Crushing wall; 26. Second feed inlet; 27. Connecting frame; 28. Discharge funnel; 101. Second motor; 102. Support. Detailed Implementation
[0021] The embodiments of this utility model will be described in further detail below with reference to the accompanying drawings and examples. The following examples are used to illustrate the technical solution of this utility model, but should not be used to limit the scope of protection of this utility model.
[0022] Example:
[0023] like Figure 1 and Figure 2 As shown, this utility model provides a bath salt melting device, including a molten salt cylinder 11 and a crushing cylinder 12. The crushing cylinder 12 is disposed above the molten salt cylinder 11, providing the basic structure for the bath salt processing flow. A first feed inlet 13 is provided at the top of the molten salt cylinder 11, and a uniform feed rack 14 is detachably connected to the bottom of the first feed inlet 13. The uniform feed rack 14 can perform preliminary dispersion processing on the bath salt falling from above, allowing the user to distribute the bath salt entering the molten salt cylinder 11 more evenly in its internal space, thus improving the device's control over the distribution of bath salt feed. A limiting frame 15 is provided below the uniform feed rack 14, and a base 16 is provided below the limiting frame 15. The limiting frame 15 and the base 16 provide support for the internal structure of the device, and also create conditions for subsequent stirring and discharging operations. They can stably support the components and materials inside the molten salt cylinder 11, allowing the user to perform subsequent molten salt operations, thus improving the overall structural stability of the device.
[0024] A stirring rod 17 is installed between the base 16 and the limiting frame 15. The stirring rod 17 allows for the mixing of the bath salt after it enters the molten salt cylinder 11 and is initially distributed by the equalizing rack 14 and the limiting frame 15. This further promotes the uniform distribution of the bath salt within the molten salt cylinder 11, enhancing the device's ability to improve the uniformity of bath salt mixing. A second motor 101 is detachably connected to the bottom of the base 16, allowing the user to power the stirring rod 17. This enables automated stirring, improving the efficiency of the stirring process and enhancing user convenience in mixing bath salts. The shaft of the second motor 101 passes through the base 16 and is connected to the stirring rod 17 via a coupling, ensuring stable power transmission and allowing the stirring rod 17 to operate stably and... For efficient operation, the base 16 is equipped with multiple sets of supports 102 around its perimeter. These supports enhance the stability of the base 16, preventing users from worrying about the equipment tipping over due to instability or insufficient support during operation, thus improving the safety of the device. One side of the base 16 has an integrally formed discharge port 18, facilitating the output of molten salt after processing. Users can easily discharge the molten bath salt through the discharge port 18, ensuring the device can smoothly complete the molten salt discharge process and improving the ease of discharge. An electromagnetic heating ring 19 is installed inside the molten salt cylinder 11. This ring generates heat to melt the bath salt, enhancing the device's ability to melt the bath salt and ensuring the realization of the bath salt melting function.
[0025] like Figure 3 and Figure 4 As shown, a crushing assembly for crushing bath salts is installed inside the crushing cylinder 12. The crushing assembly includes a mounting cylinder 21 located below the crushing cylinder 12. The mounting cylinder 21 provides installation and protection space for other components of the crushing assembly, allowing the user to properly place the components inside the crushing cylinder 12, thus improving the compactness and rationality of the device structure. A first motor 22 and a commutator 23 are respectively installed inside the mounting cylinder 21. The user can use the first motor 22 to provide power for the entire crushing process, enabling the device to start the crushing operation and improving the power guarantee capability of the device for crushing bath salts. The shaft end of the first motor 22 is located inside the commutator 23, ensuring the stability and accuracy of power transmission. A crushing platform 24 is set above the commutator 23. The crushing platform 24 is connected to the shaft end of the commutator 23 through an eccentric shaft. The eccentric shaft enables the crushing platform 24 to generate an irregular motion trajectory under the drive of the commutator 23. This special motion mode increases the contact and friction with the bath salt, allowing the user to crush the bath salt more effectively, thus improving the crushing efficiency and effect of the device on the bath salt.
[0026] The crushing cylinder 12 is equipped with a crushing wall 25. The crushing wall 25 defines a relatively enclosed space for the crushing table 24, allowing the bath salt to fully contact the crushing table 24 when crushing the bath salt. This improves the efficiency and controllability of the crushing process. The crushing table 24 is located inside the crushing wall 25, ensuring that the crushing operation is carried out within the preset area, avoiding bath salt splashing and ensuring the orderly conduct of the crushing work. The top of the crushing wall 25 is detachably connected to a second feed port 26. The user can use the second feed port 26 to transport the bath salt to be crushed into the crushing space, making it convenient to add raw materials to the device, improving the convenience of feeding the device and increasing the efficiency of adding bath salt.
[0027] A connecting frame 27 is provided between the mounting cylinder 21 and the molten salt cylinder 11. The connecting frame 27 securely connects the crushing component and the molten salt cylinder 11, ensuring the continuity and stability of the entire equipment structure and improving the overall structural stability of the device. The top of the connecting frame 27 is connected to the mounting cylinder 21 via a discharge funnel 28, and the bottom of the discharge funnel 28 is connected to the first feed inlet 13. This structure forms a material conveying channel, allowing the user to smoothly transfer the crushed bath salt from the crushing cylinder 12 into the molten salt cylinder 11. This enables the device to transfer the crushed bath salt, improving the material transfer efficiency. The bottom of the connecting frame 27 is connected to the first feed inlet 13, further strengthening the overall structural stability and ensuring that no malfunctions occur due to loose connections during material conveying, thus guaranteeing the stable operation of the equipment.
[0028] The specific usage and function of this embodiment are as follows:
[0029] First, the user pours the bath salt to be processed into the grinding cylinder 12 through the second feed port 26 at the top of the grinding wall 25. At this time, the first motor 22 is turned on. The shaft end of the first motor 22 is located in the commutator 23, providing power for the entire grinding process and driving the commutator 23 to rotate. The commutator 23 is connected to the grinding disc 24 above through an eccentric shaft, so that the grinding disc 24 generates an irregular movement trajectory, which efficiently crushes the bath salt located in the grinding wall 25. The grinding wall 25 defines a closed space for the grinding operation, ensuring that the bath salt and the grinding disc 24 are in full contact, avoiding the bath salt from splashing, and ensuring that the grinding work is carried out in an orderly manner. After being crushed, the bath salt enters the first feed port 13 at the top of the molten salt cylinder 11 through the discharge funnel 28 connected to the top of the mounting cylinder 21 and along the material conveying channel. Before entering the molten salt cylinder 11, the bath salt first passes through a uniform feed rack 14 detachably connected to the bottom of the first feed inlet 13. The uniform feed rack 14 initially disperses the salt, and then the limiting frame 15 below the uniform feed rack 14 further regulates the falling range, making the bath salt more evenly distributed in the internal space of the molten salt cylinder 11. Next, the second motor 101 detachably connected to the bottom of the base 16 is started. The second motor 101 transmits power stably to the stirring rod 17 through a coupling. The stirring rod 17 stirs and mixes the evenly distributed bath salt between the base 16 and the limiting frame 15, further promoting the even distribution of the bath salt in the molten salt cylinder 11. At the same time, the electromagnetic heating ring 19 inside the molten salt cylinder 11 is turned on to heat and melt the bath salt. During this process, multiple sets of supports 102 around the base 16 enhance the stability of the equipment and ensure operational safety. When the bath salt is completely melted, the user can conveniently discharge the melted bath salt through the integrated discharge port 18 on one side of the base 16, completing the entire bath salt melting process.
[0030] The foregoing has shown and described the basic principles, main features, and advantages of this utility model. It is obvious to those skilled in the art that this utility model is not limited to the details of the above exemplary embodiments.
Claims
1. A bath salt melting device, comprising a molten salt cylinder (11) and a crushing cylinder (12), characterized in that: The crushing cylinder (12) is positioned above the molten salt cylinder (11). The top of the molten salt cylinder (11) is provided with a first feed inlet (13). The bottom of the first feed inlet (13) is detachably connected to a uniform feeder (14). A limiting frame (15) is provided below the uniform feeder (14). A base (16) is provided below the limiting frame (15). A stirring rod (17) is provided between the base (16) and the limiting frame (15). An outlet (18) is integrally formed on one side of the base (16). An electromagnetic heating ring (19) is provided inside the molten salt cylinder (11). A crushing component for crushing bath salt is provided inside the crushing cylinder (12).
2. The bath salt melting equipment according to claim 1, characterized in that: The crushing assembly includes a mounting cylinder (21) located below the crushing cylinder (12), and a first motor (22) and a commutator (23) are respectively installed inside the mounting cylinder (21).
3. The bath salt melting equipment according to claim 2, characterized in that: The shaft end of the first motor (22) is located inside the commutator (23), and a crushing frustum (24) is provided above the commutator (23). The crushing frustum (24) is connected to the shaft end of the commutator (23) through an eccentric shaft.
4. The bath salt melting equipment according to claim 3, characterized in that: The crushing cylinder (12) is provided with a crushing wall (25), the crushing frustum (24) is located inside the crushing wall (25), and a second feed inlet (26) is detachably connected to the top of the crushing wall (25).
5. The bath salt melting equipment according to claim 2, characterized in that: A connecting frame (27) is provided between the mounting cylinder (21) and the molten salt cylinder (11), and the bottom of the connecting frame (27) is connected to the first feed port (13).
6. The bath salt melting equipment according to claim 5, characterized in that: The top of the connecting frame (27) is connected to the mounting cylinder (21) via a discharge funnel (28), and the bottom of the discharge funnel (28) is connected to the first feed inlet (13).
7. The bath salt melting equipment according to claim 1, characterized in that: The base (16) is detachably connected to a second motor (101). The shaft of the second motor (101) passes through the base (16) and is connected to the stirring rod (17) via a coupling. Multiple sets of supports (102) are provided around the base (16).