A raw salt dispensing device
By designing a raw salt mixing device with a box and weighing unit, the problems of uneven mixing and inaccurate weighing of raw salt were solved, achieving precise mixing and efficient production.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- YUNYANG SALT CO LTD
- Filing Date
- 2025-06-24
- Publication Date
- 2026-07-10
AI Technical Summary
The existing raw salt crushing equipment cannot adjust the distance between the grinding mechanisms according to the size of the raw salt, resulting in poor mixing effect and inability to mix and weigh the raw salt, which affects the production quality.
A raw salt mixing device was designed, comprising a box, a weighing unit, and a discharging assembly. The device controls the power assembly and cylinders via an intelligent display to achieve precise weighing and unloading of raw salt, ensuring uniform mixing and production quality.
It achieves precise blending of raw salt, ensuring uniformity of mixing and production quality, reducing the labor intensity of workers, and improving production efficiency.
Smart Images

Figure CN224477632U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of raw salt blending technology, and in particular to a raw salt blending device. Background Technology
[0002] The existing raw salt crushing device cannot adjust the distance between the grinding mechanisms according to the size of the raw salt, resulting in insufficient grinding of the raw salt and thus affecting the mixing effect.
[0003] A prior art patent application with publication number CN218132234U discloses a raw salt mixing device, including a support plate, an adjusting rod connected to the support plate, a fixed frame sleeved on the adjusting rod, a rotating ring connected to the fixed frame, a lower pressure plate connected to the rotating ring, and a contact rod connected to the support plate. When using the raw salt mixing device, raw salt blocks are placed in a feeding trough, and an extrusion plate is placed on top of the raw salt blocks. The connecting frame engages with the support rod, and the connecting frame drives the bottom end of the threaded rod to contact the extrusion plate through the contact toothed ring, thereby adjusting the distance between the grinding disc and the lower pressure plate and improving the grinding quality.
[0004] However, in the aforementioned prior art, it is impossible to mix and weigh the raw salt, resulting in insufficient mixing uniformity and affecting the quality of subsequent production. Utility Model Content
[0005] The purpose of this invention is to provide a raw salt mixing device, which aims to solve the problem in the prior art that the raw salt cannot be mixed and weighed, resulting in insufficient mixing uniformity and affecting the quality of subsequent production.
[0006] To achieve the above objectives, this utility model provides a raw salt blending device, including a housing and a weighing unit. The weighing unit includes multiple discharge bins, side plate frames, a support plate, two slide rods, a sliding seat frame, a weighing device, an intelligent display, a guide frame, a discharge assembly, and a power assembly. The weighing unit is connected to the housing. The multiple discharge bins are all connected to the housing and are located on the inner sidewalls of the housing. The side plate frames are fixedly connected to the housing and are located on the inner bottom wall of the housing. The support plate is disposed between the side plate frames, and the two slide rods are fixedly connected to the support plate. The side plates are located on both sides of the support plate. The side plate frame has symmetrical oblique sliding holes, which are movably engaged with the two sliding rods. The sliding base frame is rotatably connected to the support plate and is located below the support plate. The power assembly is connected to the sliding base frame and the housing respectively. The weighing device is fixedly connected to the support plate and is located above the support plate. The intelligent display is fixedly connected to the housing and is located on the outer wall of the housing. The intelligent display is also electrically connected to the weighing device. The guide frame is fixedly connected to the housing and is located on the inner wall of the housing.
[0007] The material feeding assembly includes a discharge pipe, a plug frame, a fixing ring, and a cylinder. The discharge pipe is fixedly connected to the material feeding bin and located at the output end of the material feeding bin. The fixing ring is fixedly connected to the discharge pipe and located on the outer side wall of the discharge pipe. The plug frame is detachably connected to the discharge pipe and located below the discharge pipe. The cylinder is fixedly connected to the fixing ring and located below the fixing ring. The cylinder is also electrically connected to the smart display. The output end of the cylinder is fixedly connected to the plug frame and located above the plug frame.
[0008] The feeding assembly further includes an inclined ring, which is fixedly connected to the discharge pipe and located on the inner side wall of the discharge pipe.
[0009] The power assembly includes a U-shaped plate, a screw, and a connecting plate. The U-shaped plate is fixedly connected to the housing and located below the housing. The screw is rotatably connected to the U-shaped plate and located on the inner side wall of the U-shaped plate. The connecting plate is fixedly connected to the slide frame and located on one side of the slide frame. The connecting plate is threadedly engaged with the screw. The housing has a strip-shaped hole, which is slidably engaged with the connecting plate.
[0010] The power assembly further includes a mounting bracket and a stepper motor. The mounting bracket is fixedly connected to the U-shaped plate and located on one side of the U-shaped plate. The stepper motor is fixedly connected to the mounting bracket and located on one side of the mounting bracket. The stepper motor is electrically connected to the smart display. The output end of the stepper motor is fixedly connected to the screw and located at one end of the screw.
[0011] This utility model discloses a raw salt mixing device. In use, ground raw salt is placed into the feeding hopper, and the feeding component releases the salt from the corresponding hopper. The guide frame guides the raw salt to fall onto the weighing device. The intelligent display receives the electrical signal transmitted by the weighing device in real time. After weighing, clicking the intelligent display activates the power component, causing it to move to the right against the sliding frame. Due to the sliding constraint formed by the sliding rod and the symmetrical oblique sliding hole, the support plate can rotate around the connection point with the sliding frame, completing the unloading of the raw salt. The entire process, through the coordinated operation of various components, achieves a complete workflow from raw salt storage, transportation, weighing to data display and subsequent guidance, achieving the goal of precise raw salt mixing and ensuring the uniformity of subsequent mixing and production quality. Attached Figure Description
[0012] To more clearly illustrate the technical solutions in the embodiments of this application or the prior art, the accompanying drawings used in the description of the embodiments or the prior art will be briefly introduced below.
[0013] Figure 1 This is a schematic diagram of the raw salt blending device of this utility model.
[0014] Figure 2 This is a cross-sectional view of the raw salt blending device of this utility model.
[0015] Figure 3 This is the utility model Figure 2 Enlarged view of the local structure at point A.
[0016] Figure 4 This is a right view of the raw salt blending device of this utility model.
[0017] Figure 5 This is the utility model Figure 4 BB line section view.
[0018] 101-Box body, 102-Discharge bin, 103-Side plate frame, 104-Support plate, 105-Slide rod, 106-Slide base frame, 107-Weighing device, 108-Intelligent display, 109-Guide frame, 110-Discharge pipe, 111-End cap frame, 112-Fixing ring, 113-Cylinder, 114-Beveled ring, 115-U-shaped plate, 116-Screw, 117-Connecting plate, 118-Mounting frame, 119-Stepper motor, 120-Symmetrical oblique sliding hole, 121-Strip hole. Detailed Implementation
[0019] Please see Figures 1 to 5 ,in, Figure 1 This is a schematic diagram of the raw salt blending device of this utility model. Figure 2 This is a cross-sectional view of the raw salt blending device of this utility model. Figure 3 This is the utility model Figure 2 Enlarged view of the local structure at point A. Figure 4 This is a right view of the raw salt blending device of this utility model. Figure 5 This is the utility model Figure 4 BB line section view.
[0020] This utility model provides a raw salt blending device, including a box 101 and a weighing unit. The weighing unit includes multiple feeding bins 102, a side plate frame 103, a support plate 104, two slide rods 105, a slide frame 106, a weighing device 107, an intelligent display 108, a guide frame 109, a feeding assembly, and a power assembly. The feeding assembly includes a discharge pipe 110, a plug frame 111, a fixing ring 112, a cylinder 113, and an inclined ring 114. The power assembly includes a U-shaped plate 115, a screw 116, a connecting plate 117, a mounting frame 118, and a stepper motor 119. The side plate frame 103 has symmetrical inclined sliding holes 120, and the box 101 has a strip-shaped hole 121.
[0021] The weighing unit is connected to the housing 101; multiple discharge bins 102 are all connected to the housing 101 and are located on the inner sidewall of the housing 101 respectively; the side plate frame 103 is fixedly connected to the housing 101 and is located on the inner bottom wall of the housing 101; the support plate 104 is disposed between the side plate frames 103; two sliding rods 105 are fixedly connected to the support plate 104 respectively and are located on both sides of the support plate 104; the side plate frame 103 has symmetrical oblique sliding holes 120, and the symmetrical oblique sliding holes 120 are movably engaged with the two sliding rods 105. The slide frame 106 is rotatably connected to the support plate 104 and is located below the support plate 104. The power assembly is connected to the slide frame 106 and the housing 101 respectively. The weighing device 107 is fixedly connected to the support plate 104 and is located above the support plate 104. The intelligent display 108 is fixedly connected to the housing 101 and is located on the outer side wall of the housing 101. The intelligent display 108 is electrically connected to the weighing device 107. The guide frame 109 is fixedly connected to the housing 101 and is located on the inner side wall of the housing 101.
[0022] In this embodiment, the ground raw salt is placed into the feeding hopper 102, and the feeding component releases the salt from the corresponding feeding hopper 102. The guide frame 109 guides the raw salt to fall onto the weighing device 107, while the smart display 108 receives the electrical signal transmitted by the weighing device 107 in real time. After weighing, clicking the smart display 108 activates the power component, causing it to move to the right against the slide frame 106. Since the slide rod 105 forms a sliding constraint with the symmetrical oblique sliding hole 120, the support plate 104 can rotate around the connection point with the slide frame 106, completing the unloading of the raw salt. The entire process, through the coordinated operation of various components, realizes a complete workflow from raw salt storage, transportation, weighing to data display and subsequent guidance, achieving the purpose of precise raw salt mixing and ensuring the uniformity of subsequent mixing and production quality.
[0023] The intelligent display 108 uses an XK3201 digital weighing display, suitable for static and dynamic weight monitoring and control, especially performing well in packaging and filling operations. It integrates logic control and metering control functions, and can display various data through the intelligent display. In terms of weighing control, it can automatically measure bag weight, accurately control the closing of the gate and stop filling to ensure stable bag weight. It also has zero-point dynamic automatic tracking and bag weight dynamic automatic correction functions to ensure measurement accuracy. Its logic control function is powerful. At the same time, it is equipped with five 5V output ports, which can be used to control solid-state relays, and then control the start and stop of cylinders. The status of each input and output is displayed through panel indicator lights, which makes it easy for operators to understand the operation of the equipment.
[0024] Furthermore, the discharge pipe 110 is fixedly connected to the discharge bin 102 and located at the output end of the discharge bin 102; the fixing ring 112 is fixedly connected to the discharge pipe 110 and located on the outer side wall of the discharge pipe 110; the end cap bracket 111 is detachably connected to the discharge pipe 110 and located below the discharge pipe 110; the cylinder 113 is fixedly connected to the fixing ring 112 and located below the fixing ring 112; the cylinder 113 is electrically connected to the smart display 108; and the output end of the cylinder 113 is fixedly connected to the end cap bracket 111 and located above the end cap bracket 111.
[0025] In this embodiment, clicking the smart display 108 activates the cylinder 113, causing it to move the end cap frame 111 away from the discharge pipe 110, releasing the raw salt from the corresponding discharge bin 102. This is controlled in real time in conjunction with the weighing value displayed on the smart display 108. The structure is simple and easy for operators to use.
[0026] Furthermore, the inclined ring 114 is fixedly connected to the discharge pipe 110 and is located on the inner side wall of the discharge pipe 110.
[0027] In this embodiment, the inclined ring 114 is used to contact the end cap bracket 111 to prevent the end cap bracket 111 from excessively squeezing the end of the discharge pipe 110 and extend the service life of the discharge pipe 110.
[0028] Furthermore, the U-shaped plate 115 is fixedly connected to the housing 101 and located below the housing 101; the screw 116 is rotatably connected to the U-shaped plate 115 and located on the inner side wall of the U-shaped plate 115; the connecting plate 117 is fixedly connected to the slide bracket 106 and located on one side of the slide bracket 106; the connecting plate 117 is threadedly engaged with the screw 116; the housing 101 has a strip-shaped hole 121, and the strip-shaped hole 121 is slidably engaged with the connecting plate 117.
[0029] In this embodiment, rotating the screw 116 uses the characteristics of the thread to drive the connecting plate 117 to move the slide bracket 106, thereby completing the flipping of the support plate 104 and assisting the operator in weighing.
[0030] Furthermore, the mounting bracket 118 is fixedly connected to the U-shaped plate 115 and located on one side of the U-shaped plate 115. The stepper motor 119 is fixedly connected to the mounting bracket 118 and located on one side of the mounting bracket 118. The stepper motor 119 is electrically connected to the smart display 108. The output end of the stepper motor 119 is fixedly connected to the screw 116 and located at one end of the screw 116.
[0031] In this embodiment, clicking the smart display 108 starts the stepper motor 119, which drives the screw 116 to rotate, assisting the slide frame 106 to move, which can effectively reduce the labor intensity and workload of the staff.
[0032] The above-disclosed embodiments are merely preferred embodiments of this application and should not be construed as limiting the scope of this application. Those skilled in the art will understand that all or part of the processes for implementing the above embodiments, and equivalent variations made in accordance with the claims of this application, still fall within the scope of this application.
Claims
1. A raw salt mixing device, comprising a housing, characterized in that, It also includes a weighing unit, which is connected to the housing; The weighing unit includes multiple feeding bins, side plate frames, support plates, two sliding rods, a sliding seat frame, a weighing device, a smart display, a guide frame, a feeding assembly, and a power assembly. The multiple feeding bins are all connected to the housing and are located on the inner sidewalls of the housing. The side plate frames are fixedly connected to the housing and are located on the inner bottom wall of the housing. The support plates are disposed between the side plate frames. The two sliding rods are fixedly connected to the support plates and are located on opposite sides of the support plates. The side plate frames have symmetrical oblique sliding holes that movably engage with the two sliding rods. The sliding seat frame is rotatably connected to the support plate and is located below the support plate. The power assembly is connected to both the sliding seat frame and the housing. The weighing device is fixedly connected to the support plate and is located above the support plate. The smart display is fixedly connected to the housing and is located on the outer sidewall of the housing, and is electrically connected to the weighing device. The guide frame is fixedly connected to the housing and is located on the inner sidewall of the housing.
2. The raw salt blending device as described in claim 1, characterized in that, The feeding assembly includes a discharge pipe, a plug bracket, a fixing ring, and a cylinder. The discharge pipe is fixedly connected to the feeding bin and located at the output end of the feeding bin. The fixing ring is fixedly connected to the discharge pipe and located on the outer wall of the discharge pipe. The plug bracket is detachably connected to the discharge pipe and located below the discharge pipe. The cylinder is fixedly connected to the fixing ring and located below the fixing ring. The cylinder is also electrically connected to the smart display. The output end of the cylinder is fixedly connected to the plug bracket and located above the plug bracket.
3. The raw salt blending device as described in claim 2, characterized in that, The feeding assembly also includes a beveled ring, which is fixedly connected to the discharge pipe and located on the inner side wall of the discharge pipe.
4. The raw salt blending device as described in claim 3, characterized in that, The power assembly includes a U-shaped plate, a screw, and a connecting plate. The U-shaped plate is fixedly connected to the housing and located below the housing. The screw is rotatably connected to the U-shaped plate and located on the inner side wall of the U-shaped plate. The connecting plate is fixedly connected to the slide frame and located on one side of the slide frame. The connecting plate is threadedly engaged with the screw. The housing has a strip-shaped hole, which is slidably engaged with the connecting plate.
5. The raw salt blending device as described in claim 4, characterized in that, The power assembly also includes a mounting bracket and a stepper motor. The mounting bracket is fixedly connected to the U-shaped plate and located on one side of the U-shaped plate. The stepper motor is fixedly connected to the mounting bracket and located on one side of the mounting bracket. The stepper motor is electrically connected to the smart display. The output end of the stepper motor is fixedly connected to the screw and located at one end of the screw.