Inclined transfer channel for peanut powder mixer

Abstract

The utility model provides a peanut powder mixing machine uses the inclined material turning channel relates to peanut powder mixing machine technical field, including the warehouse body, support platform, support platform welding installation is in the circumference outer wall of warehouse body, material turning device, material turning device fixed mounting is in the side wall of warehouse body, realizes to the mixture to carry out more sufficient mixing and to the adjustment of inclination angle, better adaptation equipment, material turning device includes the injection port, injection port sets up in the circumference outer wall of warehouse body, the warehouse body circumference inner wall rotation is connected with spiral shaft, the side wall welding installation of warehouse body has the connecting block, the inside slide coupling of connecting block has the motor frame, the side wall screw thread connection of motor frame and connecting block has the connecting bolt, the side wall fixed mounting of motor frame has the motor, the output fixed connection of motor has the connector. The utility model solves the problem that part of material powder may not mix evenly and the equipment inclination angle is inconvenient to adjust.

Description

Technical Field

[0001] This utility model relates to the technical field of peanut flour mixers, specifically to an inclined material transfer channel for a peanut flour mixer. Background Technology

[0002] Peanut powder is a powdered substance made from the dried and pulverized residue after peanut oil extraction, or directly from ground peanuts. It is rich in protein, unsaturated fatty acids, and trace elements, and has multiple functions including nutritional supplementation, dietary therapy, and industrial applications.

[0003] When peanut powder mixers mix various powders, sometimes some powders are not mixed evenly, and the powders may clump together, affecting the final product quality. Also, when transferring materials, different mixers have different tilt height requirements. Some machines require manual support to adjust the equipment, which is labor-intensive and resource-intensive, and reduces efficiency. Utility Model Content

[0004] This invention provides an inclined material transfer channel for a peanut flour mixer, which solves the problems mentioned in the background art.

[0005] To solve the above-mentioned technical problems, the technical solution of this utility model is as follows:

[0006] This utility model provides an inclined material transfer channel for a peanut flour mixer, comprising:

[0007] Warehouse body;

[0008] A support platform, which is welded and installed on the outer circumferential wall of the silo body;

[0009] The material transfer device is fixedly installed on the side wall of the silo body to achieve more thorough mixing of the mixture and adjust the tilt angle to better adapt to the equipment.

[0010] Through the above technical solution, the material transfer device stirs and conveys the mixed material entering the equipment, reducing the phenomenon of uneven mixing and clumping of powder in the finished product. At the same time, when used with different mixers, the tilt angle can be easily adjusted, reducing labor costs and improving processing efficiency.

[0011] Furthermore, the material transfer device includes a feeding port located on the outer circumference of the hopper body. A spiral shaft is rotatably connected to the inner circumference of the hopper body. A connecting block is welded to the side wall of the hopper body. A motor frame is slidably connected inside the connecting block. A connecting bolt is threadedly connected to the side wall of the connecting block. A motor is fixedly installed on the side wall of the motor frame. A connector is fixedly connected to the output end of the motor. The connector is slidably connected to the side wall of the spiral shaft. A discharge port is located on the outer circumference of the hopper body at the end furthest from the motor. A rear support column and a front support column are fixedly connected to the lower surface of the support platform. A placement seat is rotatably connected to the side wall of the rear support column. A sliding groove is provided on the side wall of the placement seat. A fixing bolt is slidably connected to the side wall of the rear support column. A fixing sleeve is threaded to the outer circumference of the fixing bolt. The fixing bolt passes through the sliding groove and the side wall of the rear support column and is connected to the fixing sleeve. A connecting column is fixedly connected to the side wall of the front support column. A sleeve block is rotatably connected to the outer circumference of the connecting column. A connecting sleeve is fixedly connected to the side wall of the connecting column. The connecting column passes through the front support column and the sleeve block and is connected to the connecting sleeve. A telescopic rod is fixedly connected to the lower surface of the sleeve block. A base plate is fixedly connected to the lower surface of the telescopic rod.

[0012] With the above technical solution, when the equipment needs to be used, the fixing bolt on the placement seat is rotated to release the locking of the placement seat and the rear support column. At the same time, the two telescopic rods are activated, causing them to push one end of the equipment upward through the sleeve block, connecting column, and front support column. This causes the rear support column, fixing bolt, and fixing sleeve to slide on the sliding groove. After reaching a suitable angle, the fixing bolt on the rear support column is reversed, so that the fixing bolt and fixing sleeve fix the angle position of the placement seat and the rear support column, making it easy for the equipment to be used in conjunction with the mixer. The mixer pours the mixture into the equipment through the feeding port, starts the motor, and the motor drives the screw shaft to rotate. While conveying the mixture, it also stirs and mixes the mixture to avoid uneven mixing of some powders. At the same time, it breaks up any lumps that may appear in the powder, improving the finished product effect. Then, the mixture is conveyed out of the equipment through the discharge port for collection.

[0013] Furthermore, a baffle is fixedly installed on the upper surface of the injection port, and the baffle adopts an inclined design.

[0014] The above technical solution uses a baffle to block the spilled powder and allows it to fall back into the injection port via an inclined surface, reducing waste.

[0015] Furthermore, a locking bolt is slidably connected to the outer circumferential wall of the spiral shaft and the outer circumferential wall of the connector, and a locking sleeve is threadedly connected to the outer circumferential wall of the locking bolt. The locking bolt passes through the spiral shaft and the connector and is connected to the locking sleeve.

[0016] Through the above technical solutions, the locking bolt and locking sleeve make the connection between the motor and the screw shaft more stable, and also facilitate the disassembly and installation of the motor, as well as maintenance and repair.

[0017] Furthermore, the outer circumferential wall of the spiral shaft that contacts the locking bolt has a flat opening.

[0018] The above technical solution allows for a larger contact area between the locking bolt, the locking sleeve, and the spiral shaft, resulting in a better fixing effect.

[0019] Furthermore, a pad is fixedly installed on the lower surface of the placement seat and the base plate.

[0020] Through the above technical solution, the pad provides a certain cushioning effect for the placement seat and the base plate, while reducing the wear on the bottom of the placement seat and the base plate.

[0021] Furthermore, auxiliary blocks are welded and installed on the side walls of the front and rear support columns.

[0022] Through the above technical solution, the auxiliary block makes the connection between the front and rear support columns and the support frame more stable and provides better support.

[0023] The above-described solution of this utility model has at least the following beneficial effects:

[0024] This invention uses a material transfer device to further stir and mix the materials entering the equipment, avoiding uneven mixing and caking of some powders. At the same time, when the equipment is used with different mixers, the tilt angle can be easily adjusted to adapt to different mixers, improving the versatility of the equipment, reducing manpower and material resources, and improving efficiency. Attached Figure Description

[0025] Figure 1 This is a schematic diagram of the overall structure of this utility model;

[0026] Figure 2 This is a schematic diagram of the structural assembly of the material transfer device of this utility model;

[0027] Figure 3 This is a cross-sectional schematic diagram of a portion of the material transfer device of this utility model;

[0028] Figure 4 This is a partial structural diagram of the material transfer device of this utility model.

[0029] Explanation of reference numerals in the attached figures:

[0030] 1. Bin body; 2. Support platform; 3. Transfer device; 301. Inlet; 302. Spiral shaft; 303. Connecting block; 304. Motor frame; 305. Connecting bolt; 306. Motor; 307. Connector; 308. Outlet; 309. Rear support column; 310. Placement seat; 311. Fixing bolt; 312. Fixing sleeve; 313. Front support column; 314. Connecting column; 315. Connecting sleeve; 316. Sleeve block; 317. Telescopic rod; 318. Base plate; 319. Baffle; 320. Locking bolt; 321. Locking sleeve; 322. Pad; 323. Auxiliary block. Detailed Implementation

[0031] Exemplary embodiments of the present invention will now be described in more detail with reference to the accompanying drawings. While exemplary embodiments of the present invention are shown in the drawings, it should be understood that the present invention may be implemented in various forms and should not be limited to the embodiments set forth herein. Rather, these embodiments are provided so that this invention will be thorough and complete, and will fully convey the scope of the invention to those skilled in the art.

[0032] like Figure 1 As shown, an embodiment of this utility model provides an inclined material transfer channel for a peanut flour mixer, including: a bin body 1; a support platform 2, which is welded and installed on the outer circumferential wall of the bin body 1; and a material transfer device 3, which is fixedly installed on the side wall of the bin body 1, so as to achieve more thorough mixing of the mixture and adjustment of the inclination angle, and better adapt to the equipment.

[0033] like Figures 1 to 4As shown, the material transfer device 3 includes a feeding port 301, which is located on the outer circumference of the hopper 1. A spiral shaft 302 is rotatably connected to the inner circumference of the hopper 1. A connecting block 303 is welded to the side wall of the hopper 1. A motor frame 304 is slidably connected inside the connecting block 303. A connecting bolt 305 is threadedly connected to the side wall of the motor frame 304 and the connecting block 303. A motor 306 is fixedly installed on the side wall of the motor frame 304. A connector 307 is fixedly connected to the output end of the motor 306. The connector 307 is slidably connected to the side wall of the spiral shaft 302. A discharge port 308 is located on the outer circumference of the hopper 1 at the end away from the motor 306. A rear support column 309 and a front support column 313 are fixedly connected to the lower surface of the support platform 2. The side wall of the rear support column 309... A mounting base 310 is rotatably connected, and a sliding groove is provided on the side wall of the mounting base 310. A fixing bolt 311 is slidably connected to the side wall of the rear support column 309. A fixing sleeve 312 is threadedly connected to the outer circumference of the fixing bolt 311. The fixing bolt 311 passes through the sliding groove and the side wall of the rear support column 309 and is connected to the fixing sleeve 312. A connecting column 314 is fixedly connected to the side wall of the front support column 313. A sleeve block 316 is rotatably connected to the outer circumference of the connecting column 314. A connecting sleeve 315 is fixedly connected to the side wall of the connecting column 314. The connecting column 314 passes through the front support column 313 and the sleeve block 316 and is connected to the connecting sleeve 315. A telescopic rod 317 is fixedly connected to the lower surface of the sleeve block 316. A base plate 318 is fixedly connected to the lower surface of the telescopic rod 317. When the equipment needs to be used... Loosen the fixing bolt 311 and fixing sleeve 312 on the placement seat 310 by rotating them, thus releasing the locking of the placement seat 310 and the rear support column 309, allowing the rear support column 309 to rotate and slide on the placement seat 310. Activate the two telescopic rods 317, transmitting thrust to the front support column 313 through the sleeve block 316 and connecting column 314, thereby tilting one end of the equipment. Simultaneously, this causes the rear support column 309, fixing bolt 311, and fixing sleeve 312 to slide on the sliding groove. After reaching a suitable tilt angle, stop the telescopic rods 317, and simultaneously tighten the fixing bolt 311 and fixing sleeve 312 in the opposite direction on the placement seat 310, fixing the angular position of the placement seat 310 and the rear support column 309, facilitating the equipment's use with the mixer. The mixer then passes the mixture through... The material is injected into the equipment through the inlet 301. The motor 306 is started, causing its connector 307 to drive the screw shaft 302 to rotate. This conveys and mixes the material entering the equipment, preventing uneven mixing and caking, thus improving the final product quality. The mixture is then discharged from the equipment through the outlet 308, completing the material transfer. The connecting block 303, motor frame 304, and connecting bolt 305 facilitate the disassembly and installation of the motor 306 from the equipment, providing convenience for maintenance. A baffle 319 is fixedly installed on the upper surface of the inlet 301. The baffle 319 has a sloping design, which blocks any loose powder from the mixer, causing it to fall back into the inlet 301, reducing loss.A locking bolt 320 is slidably connected to the outer circumferential wall of the spiral shaft 302 and the outer circumferential wall of the connector 307. A locking sleeve 321 is threadedly connected to the outer circumferential wall of the locking bolt 320. The locking bolt 320 passes through the spiral shaft 302 and the connector 307 and is connected to the locking sleeve 321. The locking bolt 320 and the locking sleeve 321 make the connection between the connector 307 and the spiral shaft 302 more stable and reliable during rotation. It also facilitates the disassembly and installation of the motor 306, and facilitates maintenance and repair. A flat opening is provided on the outer circumferential wall of the spiral shaft 302 where it contacts the locking bolt 320. The design increases the contact area between the locking bolt 320 and locking sleeve 321 and the threaded shaft 302, resulting in a better locking and fixing effect. A pad 322 is fixedly installed on the lower surface of the placement seat 310 and the base plate 318. The pad 322 provides cushioning for the placement seat 310 and the base plate 318, while reducing wear on the bottom of the placement seat 310 and the base plate 318. Auxiliary blocks 323 are welded to the side walls of the front support column 313 and the rear support column 309. The auxiliary blocks 323 enhance the connection stability between the front support column 313 and the rear support column 309 and the support platform 2, resulting in better overall equipment support.

[0034] In this embodiment of the invention, when the equipment is needed, the fixing bolt 311 and fixing sleeve 312 are loosened by rotating the mounting base 310, thereby releasing the locking of the mounting base 310 and the rear support column 309. This allows the rear support column 309 to rotate and slide on the mounting base 310. The two telescopic rods 317 are then activated, transmitting thrust to the front support column 313 via the sleeve block 316 and connecting column 314. This pushes one end of the equipment up and tilts it, simultaneously causing the rear support column 309, fixing bolt 311, and fixing sleeve 312 to slide on the sliding groove. After reaching a suitable tilt angle, the telescopic rods 317 are stopped, and the fixing bolt 311 and fixing sleeve 312 are tightened in the opposite direction on the mounting base 310. The fixed sleeve 312 is used to fix the angle position of the mounting base 310 and the rear support column 309, which facilitates the use of the equipment with the mixer. The mixer injects the mixture into the equipment through the feeding port 301. The baffle 319 blocks the powder scattered on the mixer, allowing it to fall back into the feeding port 301 through the inclined surface, reducing loss. The motor 306 is started, and its connector 307 drives the screw shaft 302 to rotate, conveying the mixture entering the equipment while also stirring and mixing it, avoiding uneven mixing and caking of some powder, thus improving the quality of the final product. Finally, the mixture is conveyed out of the equipment through the discharge port 308, completing the material transfer.

[0035] The above description is the preferred embodiment of this utility model. It should be noted that for those skilled in the art, several improvements and modifications can be made without departing from the principle of this utility model, and these improvements and modifications should also be considered within the protection scope of this utility model.

Claims

1. An inclined material transfer channel for a peanut flour mixer, characterized in that, include: Warehouse body (1); Support platform (2), which is welded to the outer circumferential wall of the silo body (1); The material transfer device (3) is fixedly installed on the side wall of the silo body (1) to achieve more thorough mixing of the mixture and adjustment of the tilt angle, so as to better adapt to the equipment.

2. The inclined transfer channel for the peanut flour mixer according to claim 1, characterized in that, The material transfer device (3) includes a material inlet (301), which is located on the outer circumference of the silo body (1). A spiral shaft (302) is rotatably connected to the inner circumference of the silo body (1). A connecting block (303) is welded to the side wall of the silo body (1). A motor frame (304) is slidably connected inside the connecting block (303). A connecting bolt (305) is threadedly connected between the motor frame (304) and the side wall of the connecting block (303). A motor (306) is fixedly installed on the side wall of the motor frame (304). A connector (307) is fixedly connected to the output end of the motor (306). The connector (307) is slidably connected to the side wall of the screw shaft (302). A discharge port (308) is opened on the outer circumference of the end of the hopper (1) away from the motor (306). A rear support column (309) and a front support column (313) are fixedly connected to the lower surface of the support platform (2). A placement seat (310) is rotatably connected to the side wall of the column (309). The side wall of the placement seat (310) is provided with a sliding groove. A fixing bolt (311) is slidably connected to the side wall of the rear support column (309). A fixing sleeve (312) is threaded to the outer circumference of the fixing bolt (311). The fixing bolt (311) passes through the sliding groove and the side wall of the rear support column (309) and is connected to the fixing sleeve (312). The side wall of the front support column (313) is fixedly connected to... There is a connecting column (314), and a sleeve block (316) is rotatably connected to the connecting column (314). A connecting sleeve (315) is fixedly connected to the side wall of the connecting column (314). The connecting column (314) passes through the front support column (313) and the sleeve block (316) and is connected to the connecting sleeve (315). A telescopic rod (317) is fixedly connected to the lower surface of the sleeve block (316), and a base plate (318) is fixedly connected to the lower surface of the telescopic rod (317).

3. The inclined transfer channel for the peanut flour mixer according to claim 2, characterized in that, A baffle (319) is fixedly installed on the upper surface of the injection port (301), and the baffle (319) adopts a sloping design.

4. The inclined transfer channel for the peanut flour mixer according to claim 2, characterized in that, The outer circumferential wall of the spiral shaft (302) and the outer circumferential wall of the connector (307) are slidably connected with a locking bolt (320), and the outer circumferential wall of the locking bolt (320) is threadedly connected with a locking sleeve (321). The locking bolt (320) passes through the spiral shaft (302) and the connector (307) and is connected to the locking sleeve (321).

5. The inclined transfer channel for the peanut flour mixer according to claim 4, characterized in that, The outer circumferential wall of the spiral shaft (302) that contacts the locking bolt (320) has a flat opening.

6. The inclined transfer channel for the peanut flour mixer according to claim 2, characterized in that, A pad (322) is fixedly installed on the lower surface of the placement seat (310) and the base plate (318).

7. The inclined material transfer channel for the peanut flour mixer according to claim 2, characterized in that, The side walls of the front support column (313) and the rear support column (309) are welded with auxiliary blocks (323).

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