An efficient paddy rice processing device

By adopting a support block and linkage block design in the rice processing device, and using the ring channel structure and flow guide gap to control the flow of grease, the problem of grease leakage is solved, the stability of the rotating parts and the efficiency of rice processing are improved, and the service life of the motor is extended.

CN119926791BActive Publication Date: 2026-07-14NANJING YUANWANG FUXI AGRI PROD CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Patents(China)
Current Assignee / Owner
NANJING YUANWANG FUXI AGRI PROD CO LTD
Filing Date
2024-12-25
Publication Date
2026-07-14

AI Technical Summary

Technical Problem

Existing rice processing devices experience continuous vibration during the stage of separating rice grains and husks using a motor. This causes grease to leak into the rotating parts of the motor, reducing their rotational flexibility, potentially damaging the motor, and hindering the efficient progress of rice processing.

Method used

It adopts a support block and linkage block design, and connects the motor and the rotating lever through a spiral beryllium copper wire. The ring structure of the linkage block extends the grease advance length, and the grease flow is controlled through the inlet hole and the guide gap. Combined with the filter cover, it can distinguish and filter rice grains and rice husks.

Benefits of technology

It improves the rotational smoothness of the rotating parts and the retention effect of the grease, reduces the damage of the grease to the motor, extends the service life of the motor, and improves the efficiency of filtering rice grains and rice husks.

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Abstract

The present application provides a kind of high-efficient rice processing device, belongs to the technical field of agricultural device, including support block one and the support block two of being arranged on the support block one, the support block one is connected with the support block two via helical beryllium copper wire one, the support block two is fixedly connected with motor via connecting piece, the motor is arranged with rotating lever, the motor is arranged with electric wire, the rotating lever is arranged with rotating element corresponding to the electric wire, the motor is symmetrically arranged with linkage block adapted to the rotating lever.The present application solves the problem that the existing rice processing device is easy to cause the lubricating oil leakage of motor to deviate to the rotating element in the stage of distinguishing and filtering out rice and rice hull using motor, which weakens the rotating flexibility of rotating element, easily causes motor damage, is not conducive to maintaining rice processing device and promoting the efficient progress of rice processing.
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Description

Technical fields:

[0001] This invention belongs to the field of agricultural equipment technology, specifically relating to a high-efficiency rice processing device. Background technology:

[0002] Rice processing is the stage of removing the husk and bran of rice grains. Rice grains consist of the husk, bran, embryo, and endosperm. The goal of rice processing is to separate and filter out rice grains to produce rice with better eating quality.

[0003] Existing rice processing devices experience continuous vibration during the stage of separating rice grains and husks using a motor. This vibration can cause the lubricant in the motor to leak and shift to the rotating parts, reducing their rotational flexibility and potentially damaging the motor. This hinders the maintenance of the rice processing device and the efficient progress of rice processing. Summary of the Invention:

[0004] This invention provides a highly efficient rice processing device, which aims to solve the problems of existing rice processing devices where continuous vibration during the stage of separating rice grains and husks using a motor easily causes grease leakage from the motor to the rotating parts, reducing the rotational flexibility of the rotating parts, easily causing motor damage, hindering the maintenance of the rice processing device, and hindering the efficient progress of rice processing.

[0005] This invention provides a high-efficiency rice processing device, comprising a first support block and a second support block mounted on the first support block. The first support block and the second support block are connected by a helical beryllium copper wire. A motor is fixed to the second support block via a connector. A rotating lever and an electrical wire are installed in the motor. A rotating component corresponding to the electrical wire is installed on the rotating lever. A linkage block adapted to the rotating lever is symmetrically installed in the motor. A blocking ring is installed at the end of the linkage block closer to the rotating component. The blocking ring has a second opening for the rotating lever to pass through. The inner wall of the second opening has several channels, with the channels closer to the rotating component being larger than those closer to the linkage block.

[0006] The diameter of the ring increases from the linkage block toward the rotating component.

[0007] A connecting block is installed on one end of the rotating lever that is closer to the second opening, and a passage cavity is reserved between the connecting block and the second opening.

[0008] A flange is installed on the end of the passage wall that is closer to the rotating component.

[0009] The flange is connected to the track that is closer to the rotating member.

[0010] The motor is provided with an inlet hole two. The end of the inlet hole two facing the inside of the motor is connected to a flow guide gap leading to the linkage block. The linkage block includes a ring block one and a ring block two. The ring block one is installed on the rotating lever. A passage cavity two is reserved between the ring block one and the ring block two. The flow guide gap is close to the passage cavity two.

[0011] The end of the first sealing ring closer to the second opening has a pre-reserved notch, which is connected to the second passage cavity and the first passage cavity.

[0012] The upper part of the second support block is fixedly connected to the second support plate, and the first support block is fixedly connected to the first support plate. The first spiral beryllium copper wire is located between the second support plate and the first support plate. The lower part of the second support block is connected to the first support plate via the second spiral beryllium copper wire. The second spiral beryllium copper wire is a spiral beryllium copper wire that can withstand axial tensile force.

[0013] Several filter covers are installed on the second support plate. Each filter cover has an outlet hole on its side wall. A top plate is installed on the top of the filter cover, and an inlet hole is reserved on the top plate.

[0014] The two ends of the rotating lever extend out of the motor and connect with the ring block. The ring block has a pre-drilled socket, and a balance mass block is fixedly connected to the ring block.

[0015] The beneficial effects of this invention are as follows:

[0016] 1. In this invention, the rotating lever rotates the ring block, and the supporting block 2 moves via the balancing mass block on the ring block. When the rotation speed of the rotating lever increases, it is beneficial for the supporting block 2 to distinguish between rice grains and rice husks. After the wire wound into a spiral shape runs, it generates a magnetic induction vector that rotates in space at a constant speed. The magnetic vector field then rotates via the rotating component to make the rotating lever rotate. During the rotation of the linkage block, the linkage block in the connecting cover improves the stability of the rotating lever's rotation.

[0017] 2. In this invention, the diameter of several channels of the linkage block gradually increases towards the rotating component, which is beneficial for the retention of grease. Because the grease will slowly solidify in the linkage block, during the operation of the rice processing device, if the grease advances from the linkage block through the second throughlet to the location of the rotating component, the channels help to extend the advance length of the grease through the second throughlet. The grease slowly solidifies in the channels, which helps to inhibit the grease from advancing further towards the rotating component, which is beneficial for motor maintenance and improves the plugging function of the first plug ring. It helps to inhibit the grease from advancing to the location of the rotating component, which is beneficial for the maintenance of the rotating component. The first connecting block helps to inhibit the grease from advancing towards the rotating component. The rotation of the rotating lever causes the grease on the first connecting block to rotate, throwing the grease on the first connecting block into the channels. The flange improves the inhibition function of the grease advancing in the passage cavity, which helps to limit the diameter of the passage cavity and enhances the plugging function of the passage cavity.

[0018] 3. In this invention, the second inlet hole is installed outside the connecting cover. The second inlet hole is connected to the flow guide gap. The grease is guided to the connecting cover through the second inlet hole and the flow guide gap, and then to the passage cavity two of the connecting block from one end of the linkage block away from the first plug ring. A ball is installed in the passage cavity two. The grease is guided to the passage cavity two through the rotation of the ball between the ring block one and the ring block two, which improves the flexibility of the ball's movement. The diameter of the notch is similar to that of the passage cavity two. The grease is guided to the passage cavity two through the flow guide gap. It is slowly guided downward in the passage cavity two. After being received by the notch, it is guided downward through the passage cavity one. This causes the passage two to stagnate for a while. The grease slowly solidifies in the passage. The grease that has solidified in the passage helps to prevent the grease from advancing further into the rotating part. Several passages are not connected to each other.

[0019] 4. The present invention facilitates the separation and filtering of rice grains and rice husks through several filter covers. The separated rice grains and rice husks are guided away through the outlet hole 1, while the rice grains to be processed are introduced into the filter cover through the inlet hole 1 for separation and filtering.

[0020] Other features and advantages of the invention will be set forth in the following description, and will be apparent in part from the description, or may be learned by practicing the invention. The objects and other advantages of the invention may be realized and obtained by means of the structures particularly pointed out in the description and the drawings. Attached image description:

[0021] The accompanying drawings are provided to further illustrate the invention and form part of the specification. They are used together with the embodiments of the invention to explain the invention and do not constitute a limitation thereof. In the drawings:

[0022] Figure 1 This is a structural diagram of the rice processing device of the present invention;

[0023] Figure 2 This is a structural diagram of the rice processing device of the present invention;

[0024] Figure 3 This is a structural diagram of the spiral beryllium copper wire II of the present invention;

[0025] Figure 4 This is a structural diagram of the motor in this invention;

[0026] Figure 5 This is a structural diagram of the motor of the present invention;

[0027] Figure 6 This is a structural diagram of the plug ring one in this invention;

[0028] Figure 7 This is a structural diagram of the passage cavity one in this invention;

[0029] Figure 8This is a structural diagram of the rotating lever in this invention;

[0030] Figure 9 This is a structural diagram of the rotating lever of the present invention;

[0031] Figure 10 This is a top view of the first plug ring in this invention;

[0032] Figure 11 This is a bottom view of the structure of the plug ring one in this invention;

[0033] Figure 12 This is a detailed structural diagram of the plug ring one in this invention.

[0034] Figure reference numerals: 21. Support block one; 22. Support plate one; 23. Spiral beryllium copper wire one; 24. Spiral beryllium copper wire two; 31. Motor; 32. Rotating lever; 33. Ring block; 34. Connecting cover; 35. Linkage block; 36. Plug ring one; 37. Wire; 38. Rotating component; 39. Inlet hole two; 310. Plug ring two; 41. Support block two; 42. Support plate two; 43. Connecting component; 44. Bend block; 51. Filter cover; 52. Outlet hole one; 61. Top plate; 6 2. Inlet Hole 1; 242. Connecting Rod; 243. Connecting Ring; 322. Connecting Block 1; 323. Passage Cavity 1; 332. Balance Mass Block; 342. Inner Chamber; 343. Through Port 1; 344. Connecting Block 2; 345. Screw 1; 352. Ring Block 1; 353. Ring Block 2; 243. Passage Cavity 2; 362. Through Port 2; 363. Through Port 3; 364. Ring Channel; 365. Notch; 366. Screw 2; 3642. Flange; 392. Guide Gap. Detailed implementation method:

[0035] To make the objectives, technical solutions, and advantages of the present invention clearer, the technical solutions of the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings. The same reference numerals in the drawings represent the same components. It should be noted that the described embodiments are only some, not all, of the embodiments of the present invention. All other embodiments obtained by those skilled in the art based on the described embodiments of the present invention without creative effort are within the scope of protection of the present invention.

[0036] Reference Figures 1-12This invention provides a high-efficiency rice processing device, comprising a first support block 21 and a second support block 41 mounted on the first support block 21. The first support block 21 and the second support block 41 are connected by a helical beryllium copper wire 23. A motor 31 is fixedly connected to the second support block 41. A rotating lever 32 is installed in the motor 31. An electric wire 37 is installed in the motor 31. The electric wire 37 is wound in a helical shape. A device corresponding to the electric wire 37 is installed on the rotating lever 32. The corresponding rotating component 38 is a rotating part in the motor. The motor 31 is symmetrically equipped with a linkage block 35 that matches the rotating lever 32. A blocking ring 36 is installed at the end of the linkage block 35 that is closer to the rotating component 38. A second opening 362 is reserved on the blocking ring 36 to allow the rotating lever 32 to pass through. Several channels 364 are reserved on the inner wall of the second opening 362. The channels 364 that are closer to the rotating component 38 are larger than the channels 364 that are closer to the linkage block 35.

[0037] Support block 21 is mounted on support block 21. Support block 21 is connected to support block 21 via a spiral beryllium copper wire 23. Motor 31 is fixedly connected to support block 21 via connector 43. Connector 43 is used for connection between pipe ends. Rotating lever 32 is installed inside motor 31. Both ends of rotating lever 32 protrude outside motor 31 and connect to ring block 33. Insertion port is reserved on ring block 33. Balance mass block 332 is fixedly connected to ring block 33. Rotating rotating lever 32 causes ring block 33 to rotate. Support block 21 moves via balance mass block 332 on ring block 33. When the rotation speed of rotating lever 32 increases, it is beneficial for support block 241 to perform the operation of separating rice grains and rice husks.

[0038] The motor 31 contains an electric wire 37, and the rotating lever 32 is equipped with a rotating component 38 corresponding to the electric wire 37. After the electric wire 37, which is wound in a spiral shape, runs, it generates a magnetic induction vector that rotates in space at a constant speed. This magnetic vector field then causes the rotating lever 32 to rotate via the rotating component 38. Both ends of the rotating lever 32 are equipped with linkage blocks 35, which include a first ring block 352 and a second ring block 353. The first ring block 352 surrounds the rotating lever 32. On the moving lever 32, a connecting cover 34 is symmetrically installed on the motor 31. The connecting cover 34 has a pre-reserved passage 343 for the rotating lever 32 to pass through. Inside the connecting cover 34 is a linkage block 35 corresponding to the rotating lever 32. Inside the connecting cover 34 is an inner chamber 342, which is connected to the passage 343. At the bottom of the inner chamber 342 is a connecting block 344, and a plug ring 36 is installed on the connecting block 344.

[0039] During the rotation of the linkage block 35, the linkage block 35 in the connecting cover 34 improves the smoothness of the rotation of the rotating lever 32. During the operation of the rice processing device, the motor 31 vibrates, which can cause the grease in the linkage block 35 to be guided to the rotating part 38 along with the vibration of the motor 31. The grease being guided to the rotating part 38 reduces the rotation flexibility of the rotating part 38 and can easily cause damage to the motor.

[0040] A first plug ring 36 is installed between the linkage block 35 and the rotating component 38. The inner wall of the second opening 362 of the first plug ring 36 has several channels 364 reserved. The diameter of the channels 364 increases from the linkage block 35 to the rotating component 38, which is conducive to the retention of grease. Since the grease will slowly solidify in the linkage block 35, during the operation of the rice processing device, if the grease moves from the linkage block 35 to the rotating component 38 through the second opening 362, the channels 364 help to extend the length of the grease's movement through the second opening 362. The grease slowly solidifies in the channels 364, which helps to prevent the grease from moving further into the rotating component 38, which is beneficial to the maintenance of the motor and improves the plugging function of the first plug ring 36.

[0041] The diameter of the ring channel 364 increases from the linkage block 35 toward the rotating member 38, which helps to prevent the grease from advancing to the location of the rotating member 38 and helps to maintain the rotating member 38.

[0042] A connecting block 322 is installed on the end of the rotating lever 32 closest to the second opening 362. A passage cavity 323 is reserved between the connecting block 322 and the second opening 362. The connecting block 322 helps to inhibit the grease from advancing into the rotating member 38. The rotation of the rotating lever 32 causes the grease on the connecting block 322 to rotate, throwing the grease on the connecting block 322 into the channel 364. A flange 3642 is installed on the inner wall of the second opening 362 closest to the rotating member 38. The flange 3642 is located on the passage cavity 323 and connects with the channel 364 closest to the rotating member 38. The flange 3642 enhances the function of inhibiting the grease advancing into the passage cavity 323, helps to limit the diameter of the passage cavity 323, and enhances the blocking function of the passage cavity 323.

[0043] A second inlet hole 39 is installed on the outside of the motor 31. The end of the second inlet hole 39 facing into the motor 31 is connected to a guide gap 392 leading to the linkage block 35. The linkage block 35 includes a first ring block 352 and a second ring block 353. The first ring block 352 is installed on the rotating lever 32. A passage cavity 354 is reserved between the first ring block 352 and the second ring block 353. The guide gap 392 is close to the passage cavity 354. A notch 365 is reserved at the end of the first plug ring 36 that is close to the second opening 362. The notch 365 is connected to the second passage cavity 354 and the first passage cavity 323.

[0044] The first plug ring 36 has a pre-reserved opening 363. The first plug ring 36 and the connecting cover 34 are connected by the second screw 366 protruding from the opening 363. The second plug ring 310 is installed on the opening 343. The second plug ring 310 surrounds the rotating rod 32. The second plug ring 310 helps to suppress impurity molecules from the opening 343 into the inner chamber 342, which is beneficial to the operation of the linkage block 35. The side wall of the motor 31 is connected to the connecting cover 34 by the first screw 345.

[0045] A passage cavity 354 is reserved between ring block 1 352 and ring block 2 353. The flow guide gap 392 is close to the passage cavity 354. An inlet hole 39 is installed outside the connecting cover 34. The end of the inlet hole 39 facing the motor 31 is connected to the flow guide gap 392 facing the linkage block 35. The flow guide gap 392 is located on the linkage block 35 at the end that is far from the plug ring 36. The second inlet hole 39 is installed outside the connecting cover 34. The second inlet hole 39 is connected to the guide gap 392. The grease is guided to the connecting cover 34 through the second inlet hole 39 and the guide gap 392, and then guided to the passage cavity 354 of the linkage block 35 from one end of the first plug ring 36. A ball is installed in the passage cavity 354. The grease is guided to the passage cavity 354 through the rotation of the ball between the first ring block 352 and the second ring block 353, which improves the flexibility of the ball's movement.

[0046] The end of the plug ring 36 closer to the opening 362 has a notch 365, which connects to the passage cavity 354 and the passage cavity 323. The diameter of the notch 365 is similar to that of the passage cavity 354. The grease is guided from the guide gap 392 to the passage cavity 354, and then slowly guided downwards in the passage cavity 354. After being received by the notch 365, it is guided downwards again through the passage cavity 323, causing the grease to stagnate in the channel 364 of the opening 362 for a while. The grease slowly solidifies in the channel 364. The solidified grease in the channel 364 helps to prevent the grease from advancing further into the rotating part 38, and the channels 364 are not connected to each other.

[0047] Supporting block 2 41 is fixedly connected to support plate 2 42 at its top. Supporting block 1 21 is fixedly connected to support plate 1 22. Spiral beryllium copper wire 23 is located between support plate 2 42 and support plate 1 22 of support block 1 21. Supporting block 2 41 is connected to support block 1 21 at its bottom via spiral beryllium copper wire 24. Spiral beryllium copper wire 24 is a spiral beryllium copper wire that can withstand axial tension. Bent block 44 is installed at the bottom of support block 2 41. Connecting bar 242 is installed on the inner wall of support block 1 21. Spiral beryllium copper wire 24 is connected between bent block 44 and connecting bar 242. Connecting ring 243 is installed at one end of spiral beryllium copper wire 244. Spiral beryllium copper wire 242 is installed on bent block 44 via connecting ring 243.

[0048] Several filter covers 51 are installed on the support plate 2 42. The side wall of the filter cover 51 is provided with an outlet hole 52. The filter covers 51 facilitate the separation and filtering of rice and rice husks. The separated rice and rice husks are guided away from the device through the outlet hole 52. A top plate 61 is installed on the top of the filter cover 51. An inlet hole 62 is reserved on the top plate 61. The rice to be processed enters the filter cover 51 through the inlet hole 62 for separation and filtering.

[0049] The foregoing has shown and described the basic principles, main features, and advantages of the present invention. Those skilled in the art should understand that the present invention is not limited to the above embodiments. The embodiments and descriptions in the specification are merely illustrative of the principles of the invention. Various changes and modifications can be made to the invention without departing from its spirit and scope, and all such changes and modifications fall within the scope of the present invention as claimed. The scope of protection of this invention is defined by the appended claims and their equivalents.

Claims

1. A high-efficiency rice processing device, comprising a first support block (21) and a second support block (41) mounted on the first support block (21), characterized in that, The first support block (21) and the second support block (41) are connected by a spiral beryllium copper wire (23). The second support block (41) is fixed to a motor (31) via a connector (43). A rotating lever (32) is installed in the motor (31). An electric wire (37) is installed in the motor (31). A rotating component (38) corresponding to the electric wire (37) is installed on the rotating lever (32). A linkage block (35) adapted to the rotating lever (32) is symmetrically installed in the motor (31). The linkage block (35) is located at a distance from the first support block (21). A stop ring (36) is installed at one end of the rotating component (38). A passage (362) is provided on the stop ring (36) for the rotating lever (32) to pass through. Several channels (364) are reserved on the inner wall of the passage (362). The channels (364) closer to the rotating component (38) are larger than those closer to the linkage block (35). The diameter of the channels (364) increases from the linkage block (35) toward the rotating component (38). A connecting rod is installed at one end of the rotating lever (32) closer to the passage (362). Connecting block one (322), a passage cavity one (323) is reserved between the connecting block one (322) and the passage two (362). A flange (3642) is installed on the inner wall of the passage two (362) closer to the rotating part (38). The flange (3642) is connected to the ring channel (364) closer to the rotating part (38). The upper part of the supporting block two (41) is fixedly connected to the supporting plate two (42). The supporting block one (21) is fixedly connected to the supporting plate one (22). The spiral beryllium copper wire one (23) is located at the bearing Between the support plate 2 (42) and the support plate 1 (21) of the support block 1 (21), the lower end of the support block 2 (41) and the support block 1 (21) are connected by a spiral beryllium copper wire 2 (24). The spiral beryllium copper wire 2 (24) is a spiral beryllium copper wire that can withstand axial tension. Several filter covers (51) are installed on the support plate 2 (42). The filter cover (51) has an outlet hole 1 (52) installed on its side wall. The filter cover (51) has a top plate (61) installed on its top. The top plate (61) has a pre-reserved inlet hole 1 (62).

2. The high-efficiency rice processing device as described in claim 1, characterized in that, The motor (31) is provided with an inlet hole 2 (39). The end of the inlet hole 2 (39) facing the motor (31) is connected to a flow guide gap (392) leading to the linkage block (35). The linkage block (35) includes a ring block 1 (352) and a ring block 2 (353). The ring block 1 (352) is installed on the rotating lever (32). A passage cavity 2 (354) is reserved between the ring block 1 (352) and the ring block 2 (353). The flow guide gap (392) is close to the passage cavity 2 (354).

3. The high-efficiency rice processing device as described in claim 2, characterized in that, The end of the first plug ring (36) closer to the second opening (362) has a notch (365) which is connected to the second passage cavity (354) and the first passage cavity (323).

4. The high-efficiency rice processing device as described in claim 1, characterized in that, The two ends of the rotating lever (32) extend out of the motor (31) and connect with the ring block (33). The ring block (33) has a reserved insertion port, and the balance mass block (332) is fixedly connected to the ring block (33).