Automatic eggbeating machine for food processing
By using a planetary gear set driven by a hydraulic telescopic rod and a symmetrical stirring blade design, the problems of long whipping time and uneven bubbles in traditional egg beaters are solved, achieving fast and uniform egg beating and improved equipment stability.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- HEBEI KANGYUAN XIANGMEIKE FOOD
- Filing Date
- 2025-07-04
- Publication Date
- 2026-06-26
AI Technical Summary
Traditional egg beaters struggle to break the surface tension of egg liquid quickly, resulting in long beating times, uneven bubble distribution, and the single-shaft mixing method can easily lead to equipment wear and egg liquid splashing.
The system employs a planetary gear set and transmission belt system driven by a hydraulic telescopic rod, combined with a symmetrically distributed stirring blade design, to achieve rapid and uniform mixing of the egg liquid. The compound motion breaks up the egg liquid stratification, enhancing the stability and cleanliness of the equipment.
It enables rapid and uniform whipping of egg liquid, improves whipping efficiency and product quality, reduces equipment vibration and wear, and enhances operational safety and equipment hygiene.
Smart Images

Figure CN224402820U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of food processing technology, specifically to an automatic egg beater for food processing. Background Technology
[0002] In the food processing industry, whipping eggs is a crucial step in making baked goods such as cakes and egg tarts. Traditional egg beaters generally suffer from the following technical bottlenecks: manual or single-shaft mixing methods struggle to quickly break the surface tension of the egg mixture, resulting in long whipping times and uneven distribution of air bubbles within the egg mixture, affecting the fluffiness of the baked goods. Furthermore, they cannot adjust the mixing depth according to the amount of egg mixture; when the amount of egg mixture is small, the mixing head is prone to colliding with the bottom of the container, causing equipment wear or egg splattering.
[0003] A food processing egg beater (publication number: CN210445578U) according to a utility model includes: a base, a support plate fixedly connected to the left side of the top of the base, an egg beater body fixedly connected to the top of the support plate, a support frame fixedly connected to the right side of the support plate, a material bucket movably connected to the inner side of the support frame, a power groove opened inside the base, and a motor fixedly connected to the rear side of the inner wall of the power groove. This utility model, through the coordinated use of the base, support plate, egg beater body, support frame, material bucket, power groove, motor, first gear, second gear, fixed column, sliding column, and transmission mechanism, solves the problem that existing egg beaters cannot quickly break up eggs, leading to reduced efficiency in pastry making. This food processing egg beater has the advantage of quickly breaking up eggs, making it convenient for users and improving their profits.
[0004] The aforementioned application uses a single stirring shaft design, which requires a long time to whip the egg liquid. The single-shaft stirring method is difficult to quickly break the surface tension of the egg liquid, resulting in uneven distribution of air bubbles inside the egg liquid. Therefore, we propose an efficient, intelligent, and easy-to-clean automatic egg beater to meet the high-quality requirements of the food processing industry for whipping egg liquid. Utility Model Content
[0005] This invention proposes an automatic egg beater for food processing, which solves the problem in related technologies where single-shaft stirring is difficult to quickly break the surface tension of egg liquid, resulting in long beating time and uneven bubble distribution.
[0006] According to one aspect, at least one embodiment of the present invention provides an automatic egg beater for food processing, comprising: a base, a hydraulic telescopic rod fixedly connected to the top of the base, a support plate fixedly connected to the telescopic end of the hydraulic telescopic rod, a motor disposed on the top of the support plate, the output end of the motor penetrating through the bottom of the support plate and the penetrating part being rotatably connected, a motor support seat fixedly connected to the circumferential surface of the motor, one end of the motor support seat being fixedly connected to the top of the support plate, a control button disposed on the side of the hydraulic telescopic rod, and a stirring device disposed at the bottom of the support plate;
[0007] The stirring device includes a drive pulley, which is fixedly connected to the circumferential surface of the motor output shaft. A transmission belt is provided on the circumferential surface of the drive pulley. A rotating shaft is provided on the top of the support plate on the side away from the motor support base. One end of the rotating shaft passes through the bottom of the support plate, and the through part is rotatably connected. A driven pulley is fixedly connected to the circumferential surface of the other end of the rotating shaft. The circumferential surface of the drive pulley is connected to the circumferential surface of the driven pulley via the transmission belt. A planetary gear set is provided on the circumferential surface of the rotating shaft passing through one end of the support plate. The planetary gear set includes a driving gear. The inner circumferential surface of the driving gear is fixedly connected to the circumferential surface of a rotating shaft passing through one end of a support plate. An internal gear ring is fixedly connected to the bottom of the support plate. A sliding groove is formed on the top of the inner wall of the internal gear ring. A gear shaft one and a gear shaft two are slidably connected to the inner wall of the sliding groove. A gear one is fixedly connected to the circumferential surface of the gear shaft one, and a gear two is fixedly connected to the circumferential surface of the gear shaft two. The gear one meshes with the driving gear and the internal gear ring, and the gear two meshes with the driving gear and the internal gear ring.
[0008] For example, in at least one embodiment of this utility model, an automatic egg beater for food processing is provided, which further includes: a set of stirring blades fixedly connected to one end of gear shaft one and one end of gear shaft two, respectively; through holes are provided on the side of the stirring blades; and the set of stirring blades includes three blades. Each of the gear shaft one and gear shaft two ends has a set of stirring blades, each set containing three blades with through holes. The through hole design increases the contact area between the egg liquid and air, improving beating efficiency. The arrangement of the three blades forms a three-dimensional stirring space, which, combined with the centrifugal force when the blades rotate, causes the egg liquid to generate vortices during stirring, effectively breaking up the egg liquid stratification, reducing blind spots in the stirring process, and achieving rapid and uniform mixing of the egg liquid.
[0009] The first gear shaft and the second gear shaft are symmetrical about each other along the vertical central axis of the first rotating shaft, and the diameter of the first gear shaft is equal to the diameter of the second gear shaft. The symmetrical distribution of the first and second gear shafts along the vertical central axis of the first rotating shaft, with their equal diameters, ensures that the two sets of stirring blades revolve around the first rotating shaft at the same speed and trajectory, while simultaneously rotating due to the gear meshing relationship, forming a symmetrical and balanced stirring force. This design avoids the vortex deviation of the egg liquid caused by unilateral stirring, reduces equipment vibration, ensures that the egg liquid is subjected to uniform force during stirring, and improves the whipping quality and the operational stability of the stirring device.
[0010] A cover plate is fixedly connected to the bottom of the internal gear ring, and a sliding groove is formed at the bottom of the cover plate. The cover plate and sliding groove structure at the bottom of the internal gear ring provide a closed sliding guide space for gear shaft one and gear shaft two, preventing egg liquid or impurities from entering the planetary gear set during egg beating, and avoiding jamming or wear at the gear meshing point due to contamination; the cover plate enhances the structural rigidity of the internal gear ring, and together with the limiting effect of the sliding groove, ensures the axial stability of the gear shaft when rotating at high speed, extends the service life of the transmission components, and facilitates disassembly and cleaning, maintaining the hygiene of the equipment.
[0011] The diameter of the driving pulley is equal to the diameter of the driven pulley, and the driving and driven pulleys are located on the same horizontal plane. The design of the driving and driven pulleys having the same diameter and being coplanar ensures that the power output from the motor is transmitted to the rotating shaft without loss or deviation through the transmission belt, maintaining a constant speed of the planetary gear set. The stable transmission ratio avoids speed fluctuations or belt slippage caused by differences in pulley diameter or positional offsets, ensuring consistent rotation frequency and force of the mixing blades, guaranteeing even force on the egg liquid during beating, and improving beating efficiency and product quality.
[0012] According to another aspect, at least one embodiment of this utility model also provides an automatic egg beater for food processing, comprising: a rotating device provided at the bottom of the support plate, the rotating device including a second rotating shaft, one end of the second rotating shaft being fixedly connected to one end of the output shaft of a motor, a transmission box being fixedly connected to the top of the base, the other end of the second rotating shaft passing through the top of the transmission box, and the passing part being rotatably connected, a small gear being fixedly connected to the other end of the second rotating shaft, a support shaft being rotatably connected to the bottom of the inner wall of the transmission box, a large gear being fixedly connected to the circumferential surface of the support shaft, the small gear meshing with the large gear, a threaded column being fixedly connected to the top of the support shaft at the end away from the large gear, a material trough base being threadedly connected to the circumferential surface of the threaded column, and a material trough being snapped into the top of the material trough base.
[0013] For example, in at least one embodiment of this utility model, an automatic egg beater for food processing further includes: the circumferential surface of the feed trough base is slidably connected to the circumferential surface of the top side of the transmission box, and a screw moving groove is provided at the bottom of the feed trough base. The slidable connection between the circumferential surface of the feed trough base and the top of the transmission box, in conjunction with the screw moving groove at the bottom, allows the feed trough base to slide smoothly along the axis of the threaded column, while simultaneously achieving height movement through the rotation of the threaded column.
[0014] The large gear has four spokes at its top, which are symmetrically arranged along the vertical central axis of the support shaft. These four symmetrical spokes at the top of the large gear enhance its structural strength and resistance to deformation, effectively disperse centrifugal force during high-speed rotation, and reduce wheel deformation.
[0015] The support shaft and the rotating shaft are located on the same vertical central axis. When the material trough base is located at one end of the displacement trajectory, the bottom of the material trough is not located at one end of the gear shaft's stirring blade. The support shaft and the rotating shaft being on the same vertical central axis ensure that the movement trajectories of the rotating device and the stirring device are highly coaxial, avoiding mechanical interference caused by axis misalignment. When the material trough base is displaced to the end point, the bottom of the material trough maintains a safe distance from the stirring blade, preventing damage from collision between the blade and the material trough during stirring. This also facilitates changing or adjusting the position of the material trough without stopping stirring, improving operational safety and process continuity.
[0016] A limiting ring one is fixedly connected to the circumferential surface of the feed trough base, and a limiting ring two is fixedly connected to the circumferential surface of the inner wall of the transmission box. The cooperation of the limiting ring one and the limiting ring two limits the movement range of the feed trough, preventing it from sliding excessively along the threaded post, which could lead to disengagement or jamming. This ensures accurate positioning of the feed trough and guarantees the stability and reliability of material feeding and collection during the egg beating process.
[0017] The working principle and beneficial effects of this utility model are as follows:
[0018] 1. In this invention, a motor drives the active pulley to rotate, which in turn drives the driven pulley and shaft one to rotate via a transmission belt. This causes the active gear of the planetary gear set to rotate synchronously. Gear one and gear two, under the meshing action of the active gear and the inner gear ring, drive gear shaft one and gear shaft two to both revolve around shaft one and rotate on their own axis, achieving a compound motion of the stirring blades and enabling high-speed whipping of the egg mixture. The active and driven pulleys are of the same diameter and coplanar, ensuring stable transmission. Gear shaft one and gear two are symmetrically distributed along shaft one and have the same diameter, ensuring balanced force on the stirring blades and forming symmetrical vortices. The through holes on the side of the blades increase the contact area between the egg mixture and air, quickly breaking up the egg mixture stratification and improving whipping efficiency and uniformity. The bottom cover plate and sliding groove structure of the inner gear ring protect the gear set from contamination, enhancing the stability and hygiene of the stirring device.
[0019] 2. In this utility model, the output shaft of the motor drives the second rotating shaft to rotate. The small gear meshes with the large gear, causing the support shaft and the threaded column to rotate. The material trough base moves along the thread of the threaded column to achieve lifting and lowering, and the material trough moves circumferentially on the top of the transmission box. The four symmetrical spokes of the large gear enhance the structural rigidity and reduce rotational vibration. The cooperation of the first and second limit rings prevents excessive slippage or jamming, ensuring accurate positioning of the material trough. The vertical center axis of the support shaft and the first rotating shaft coincides to avoid motion interference. When the material trough base is displaced to the end point, the material trough and the stirring blade maintain a safe distance, which facilitates the replacement of the material trough or adjustment of the stirring depth. This achieves coordinated operation of the egg liquid addition and stirring process, improving the operational flexibility of the equipment and the safety of the egg beating process. Attached Figure Description
[0020] The preferred embodiments will be described below in a clear and easy-to-understand manner, in conjunction with the accompanying drawings, to further explain the above-mentioned characteristics, technical features, advantages and implementation methods of this utility model.
[0021] Figure 1 This is a three-dimensional appearance diagram of the present invention;
[0022] Figure 2 This is a schematic diagram of the structure of the present invention in a three-dimensional partial cross-section;
[0023] Figure 3 This is a schematic diagram of the structure of the three-dimensional stirring device of this utility model;
[0024] Figure 4 This is a schematic diagram of the structure of the three-dimensional rotating device of this utility model;
[0025] In the diagram: 1. Base; 2. Hydraulic telescopic rod; 3. Support plate; 4. Motor; 5. Motor support seat; 6. Control button; 7. Stirring device; 701. Drive pulley; 702. Transmission belt; 703. Shaft 1; 704. Driven pulley; 705. Planetary gear set; 70501. Drive gear; 70502. Internal gear ring; 70503. Slide groove; 70504. Gear shaft 1; 70505. Gear shaft 2; 70506. Gear 1; 70507. Gear 2; 8. Rotating device; 801. Shaft 2; 802. Transmission box; 803. Small gear; 804. Support shaft; 805. Large gear; 806. Threaded column; 807. Material trough base; 9. Material trough. Detailed Implementation
[0026] To more clearly illustrate the technical solutions in the embodiments of this utility model or the prior art, the specific implementation methods of this utility model will be described below with reference to the accompanying drawings. Obviously, the drawings described below are merely some embodiments of this utility model. For those skilled in the art, other drawings and other implementation methods can be obtained based on these drawings without any creative effort.
[0027] To keep the drawings concise, only the parts relevant to the utility model are shown schematically in each drawing; these do not represent the actual structure of the product. Furthermore, for ease of understanding, in some drawings, only one of the components with the same structure or function is schematically shown, or only one is labeled. In this document, "a" not only means "only one," but can also mean "more than one," and "several" includes "two" and "more than two."
[0028] In this document, it should be noted that, unless otherwise explicitly specified and limited, the terms "installation," "connection," and "linking" should be interpreted broadly. For example, they can refer to fixed connections, detachable connections, or integral connections; they can refer to mechanical connections or electrical connections; they can refer to direct connections or indirect connections through an intermediate medium; and they can refer to the internal connection between two components. Those skilled in the art can understand the specific meaning of the above terms in this utility model based on the specific circumstances.
[0029] Furthermore, in the description of this application, the terms "first," "second," etc., are used only to distinguish descriptions and should not be construed as indicating or implying relative importance.
[0030] like Figures 1-4 As shown, an automatic egg beater for food processing according to an embodiment of the present invention is provided, comprising: a base 1, a hydraulic telescopic rod 2 fixedly connected to the top of the base 1, a support plate 3 fixedly connected to the telescopic end of the hydraulic telescopic rod 2, a motor 4 provided on the top of the support plate 3, the output end of the motor 4 penetrating through the bottom of the support plate 3 and the penetrating part being rotatably connected, a motor support seat 5 fixedly connected to the circumferential surface of the motor 4, one end of the motor support seat 5 fixedly connected to the top of the support plate 3, a control button 6 provided on the side of the hydraulic telescopic rod 2, and a stirring device 7 provided at the bottom of the support plate 3;
[0031] The stirring device 7 includes a drive pulley 701, which is fixedly connected to the circumferential surface of the output shaft of the motor 4. A transmission belt 702 is provided on the circumferential surface of the drive pulley 701. A rotating shaft 703 is provided on the top of the side of the support plate 3 away from the motor support base 5. One end of the rotating shaft 703 passes through the bottom of the support plate 3, and the passing part is rotatably connected. A driven pulley 704 is fixedly connected to the circumferential surface of the other end of the rotating shaft 703. The circumferential surface of the drive pulley 701 is connected to the circumferential surface of the driven pulley 704 through the transmission belt 702. A planetary gear set 705 is provided on the circumferential surface of the rotating shaft 703 that passes through one end of the support plate 3. The planetary gear set 705 includes a drive gear 70501 and a drive gear 70502. The inner circumferential surface of 501 is fixedly connected to the circumferential surface of the rotating shaft 703 that passes through one end of the support plate 3. The bottom of the support plate 3 is fixedly connected to the inner gear ring 70502. The top of the inner wall of the inner gear ring 70502 is provided with a sliding groove 70503. The inner wall of the sliding groove 70503 is slidably connected to the gear shaft 70504 and the gear shaft 70505. The circumferential surface of the gear shaft 70504 is fixedly connected to the gear 70506. The circumferential surface of the gear shaft 70505 is fixedly connected to the gear 70507. The gear 70506 meshes with the driving gear 70501 and the inner gear ring 70502. The gear 70507 meshes with the driving gear 70501 and the inner gear ring 70502.
[0032] In some examples, the design also includes: a set of stirring blades fixedly connected to one end of gear shaft 1 70504 and one end of gear shaft 2 70505, respectively. The stirring blades have through holes on their sides, and each set of stirring blades contains three blades. Each set of stirring blades at the end of gear shaft 1 70504 and gear shaft 2 70505 contains three blades with through holes. The through-hole design increases the contact area between the egg liquid and air, improving whipping efficiency. The arrangement of the three blades forms a three-dimensional stirring space. Combined with the centrifugal force when the blades rotate, this generates vortices in the egg liquid during stirring, effectively breaking up egg liquid stratification, reducing blind spots in the stirring process, and achieving rapid and uniform mixing of the egg liquid.
[0033] Gear shaft 1 (70504) and gear shaft 2 (70505) are symmetrical about each other along the vertical central axis of shaft 1 (703), and the diameter of gear shaft 1 (70504) is equal to the diameter of gear shaft 2 (70505). The symmetrical distribution and equal diameter of gear shaft 1 (70504) and gear shaft 2 (70505) along the vertical central axis of shaft 1 (703) ensures that the two sets of stirring blades revolve around shaft 1 (703) at the same speed and trajectory, while simultaneously rotating due to the gear meshing, forming a symmetrical and balanced stirring force. This design avoids the vortex deviation of the egg liquid caused by unilateral stirring, reduces equipment vibration, ensures uniform force on the egg liquid during stirring, and improves the whipping quality and operational stability of the stirring device 7.
[0034] A cover plate is fixedly connected to the bottom of the internal gear ring 70502, and a sliding groove 70503 is provided at the bottom of the cover plate. The cover plate and sliding groove 70503 structure at the bottom of the internal gear ring 70502 provide a closed sliding guide space for gear shaft 1 70504 and gear shaft 2 70505, preventing egg liquid or impurities from entering the interior of the planetary gear set 705 during egg beating, and avoiding jamming or wear at the gear meshing point due to contamination; the cover plate enhances the structural rigidity of the internal gear ring 70502, and together with the limiting function of the sliding groove 70503, ensures the axial stability of the gear shaft when rotating at high speed, extends the service life of the transmission components, and facilitates disassembly and cleaning, maintaining the hygiene of the equipment.
[0035] The diameter of the driving pulley 701 is equal to the diameter of the driven pulley 704, and the driving pulley 701 and the driven pulley 704 are located on the same horizontal plane. The design of the driving pulley 701 and the driven pulley 704 having the same diameter and being coplanar ensures that the power output by the motor 4 is transmitted to the rotating shaft 703 without loss or deviation through the transmission belt 702, maintaining a constant speed of the planetary gear set 705. The stable transmission ratio avoids speed fluctuations or belt slippage caused by differences in pulley diameter or positional deviation, keeping the rotation frequency and force of the mixing blades consistent, ensuring that the egg liquid is subjected to uniform force during the egg beating process, and improving beating efficiency and product quality.
[0036] For example, such as Figures 1-4 As shown, after the motor 4 starts, the output shaft drives the drive pulley 701 to rotate, and transmits power to the driven pulley 704 through the transmission belt 702, driving the rotating shaft 703 to rotate. The end of the rotating shaft 703 that passes through the support plate 3 is fixedly connected to the drive gear 70501. The drive gear 70501 meshes with the inner wall of the inner gear ring 70502, simultaneously driving gear shaft 70504 and gear shaft 70505 to revolve along the groove 70503 of the inner gear ring 70502. Since gears 70506 and 70507 mesh with the drive gear 70501 and the inner gear ring 70502 respectively, gear shafts 70504 and 70505 rotate simultaneously while revolving, causing the end-effector stirring blades to form a combined motion of revolution and rotation.
[0037] like Figures 1-4As shown, this invention illustrates an automatic egg beater for food processing, which is largely the same as the technical solution of embodiment 1. Therefore, only the differences are described, including: a rotating device 8 is provided at the bottom of the support plate 3, the rotating device 8 includes a second rotating shaft 801, one end of the second rotating shaft 801 is fixedly connected to one end of the output shaft of the motor 4, a transmission box 802 is fixedly connected to the top of the base 1, the other end of the second rotating shaft 801 passes through the top of the transmission box 802, and the passing part is rotatably connected, a small gear 803 is fixedly connected to the other end of the second rotating shaft 801, a support shaft 804 is rotatably connected to the bottom of the inner wall of the transmission box 802, a large gear 805 is fixedly connected to the circumferential surface of the support shaft 804, the small gear 803 and the large gear 805 mesh with each other, a threaded column 806 is fixedly connected to the top of the end of the support shaft 804 away from the large gear 805, a material trough base 807 is threadedly connected to the circumferential surface of the threaded column 806, and a material trough 9 is snapped into the top of the material trough base 807.
[0038] In some examples, the circumferential surface of the trough base 807 is slidably connected to the circumferential surface of the top side of the transmission box 802, and a screw moving groove is provided at the bottom of the trough base 807. The slidable connection between the circumferential surface of the trough base 807 and the top of the transmission box 802, together with the screw moving groove at the bottom, allows the trough base 807 to slide smoothly along the axis of the threaded column 806, while the rotation of the threaded column 806 achieves vertical movement.
[0039] The top of the large gear 805 has four spokes, which are symmetrical about each other along the vertical central axis of the support shaft 804. The four symmetrical spokes on the top of the large gear 805 enhance the structural strength and deformation resistance of the gear, effectively disperse the centrifugal force during high-speed rotation, and reduce the deformation of the gear body.
[0040] With the support shaft 804 and the rotating shaft 703 located on the same vertical central axis, and the material trough base 807 at one end of the displacement trajectory, the bottom of the material trough 9 is not located at one end of the stirring blade of the gear shaft 70504. The support shaft 804 and the rotating shaft 703 being on the same vertical central axis ensure that the movement trajectories of the rotating device 8 and the stirring device 7 are highly coaxial, avoiding mechanical interference caused by axis misalignment. When the material trough base 807 is moved to the end point, the bottom of the material trough 9 maintains a safe distance from the stirring blades, preventing damage from collisions between the blades and the material trough 9 during stirring. This also facilitates changing or adjusting the position of the material trough 9 without stopping stirring, improving operational safety and process continuity.
[0041] A limiting ring 1 is fixedly connected to the circumferential surface of the material trough base 807, and a limiting ring 2 is fixedly connected to the inner circumferential surface of the transmission box 802. Through the cooperation of the limiting ring 1 and the limiting ring 2, the movement range of the material trough 9 is limited, preventing it from sliding excessively along the threaded post 806, which could lead to detachment or jamming. This ensures that the material trough 9 is accurately positioned and guarantees the stability and reliability of material feeding and collection during the egg beating process.
[0042] For example, such as Figures 1-4 As shown, the output shaft of motor 4 synchronously drives the rotating shaft 801 to rotate, and the small gear 803 at the end meshes with the large gear 805, driving the support shaft 804 and the top threaded column 806 to rotate. The material trough base 807 is threadedly connected to the threaded column 806 through the bottom screw moving groove, and its circumferential surface is slidably connected to the top of the transmission box 802. It rises and falls along the axial direction as the threaded column 806 rotates. At the same time, due to the rotation of the large gear 805, it rotates around the support shaft 804, driving the material trough 9 to perform a spiral lifting and lowering motion.
[0043] It should be noted that the above embodiments are only used to illustrate the technical solution of this utility model and are not intended to limit it. Although this utility model has been described in detail with reference to preferred embodiments, those skilled in the art should understand that modifications or equivalent substitutions can be made to the technical solution of this utility model without departing from the spirit and scope of the technical solution of this utility model, and all such modifications or substitutions should be covered within the scope of the claims of this utility model.
Claims
1. An automatic eggbeating machine for food processing, characterized by comprising: Includes a base (1), a hydraulic telescopic rod (2) is fixedly connected to the top of the base (1), a support plate (3) is fixedly connected to the telescopic end of the hydraulic telescopic rod (2), a motor (4) is provided on the top of the support plate (3), the output end of the motor (4) passes through the bottom of the support plate (3), and the passing part is rotatably connected, a motor support seat (5) is fixedly connected to the circumferential surface of the motor (4), one end of the motor support seat (5) is fixedly connected to the top of the support plate (3), a control button (6) is provided on the side of the hydraulic telescopic rod (2), and a stirring device (7) is provided at the bottom of the support plate (3). The stirring device (7) includes a drive pulley (701), which is fixedly connected to the circumferential surface of the output shaft of the motor (4). A transmission belt (702) is provided on the circumferential surface of the drive pulley (701). A rotating shaft (703) is provided on the top of the side of the support plate (3) away from the motor support seat (5). One end of the rotating shaft (703) passes through the bottom of the support plate (3), and the passing part is rotatably connected. A driven pulley (704) is fixedly connected to the circumferential surface of the other end of the rotating shaft (703). The circumferential surface of the drive pulley (701) is connected to the circumferential surface of the driven pulley (704) through the transmission belt (702). A planetary gear set (705) is provided on the circumferential surface of one end of the rotating shaft (703). The planetary gear set (705) includes a drive gear (70501). The inner circumferential surface of the moving gear (70501) is fixedly connected to the circumferential surface of the rotating shaft (703) that passes through one end of the support plate (3). The bottom of the support plate (3) is fixedly connected to an inner gear ring (70502). A sliding groove (70503) is provided on the top of the inner wall of the inner gear ring (70502). The inner wall of the sliding groove (70503) is slidably connected to a gear shaft (70504) and a gear shaft (70505). Gear 1 (70506) is fixedly connected to the circumferential surface of gear shaft 1 (70504), and gear 2 (70507) is fixedly connected to the circumferential surface of gear shaft 2 (70505). Gear 1 (70506) meshes with driving gear (70501) and internal gear ring (70502), and gear 2 (70507) meshes with driving gear (70501) and internal gear ring (70502).
2. The automatic egg beater for food processing according to claim 1, wherein A set of stirring blades is fixedly connected to one end of gear shaft one (70504) and one end of gear shaft two (70505). The stirring blades have through holes on their sides, and the set of stirring blades includes three blades.
3. The automatic egg beater for food processing according to claim 2, wherein The first gear shaft (70504) and the second gear shaft (70505) are symmetrical about each other along the vertical central axis of the first shaft (703), and the diameter of the first gear shaft (70504) is equal to the diameter of the second gear shaft (70505).
4. The automatic egg beater for food processing according to claim 3, wherein The bottom of the internal gear ring (70502) is fixedly connected to a cover plate, and the bottom of the cover plate is provided with a sliding groove (70503).
5. The automatic egg beater for food processing according to claim 4, wherein The diameter of the driving pulley (701) is equal to the diameter of the driven pulley (704), and the driving pulley (701) and the driven pulley (704) are located on the same horizontal plane.
6. The automatic egg beater for food processing according to claim 5, wherein A rotating device (8) is provided at the bottom of the support plate (3). The rotating device (8) includes a second rotating shaft (801). One end of the second rotating shaft (801) is fixedly connected to one end of the output shaft of the motor (4). A transmission box (802) is fixedly connected to the top of the base (1). The other end of the second rotating shaft (801) passes through the top of the transmission box (802), and the passing part is a rotatable connection. A small gear (803) is fixedly connected to the other end of the second rotating shaft (801). A support shaft (804) is rotatably connected to the bottom of the inner wall of the box (802). A large gear (805) is fixedly connected to the circumferential surface of the support shaft (804). The small gear (803) meshes with the large gear (805). A threaded column (806) is fixedly connected to the top of the support shaft (804) away from the large gear (805). A material trough base (807) is threadedly connected to the circumferential surface of the threaded column (806). A material trough (9) is snapped into the top of the material trough base (807).
7. The automatic egg beater for food processing according to claim 6, wherein The circumferential surface of the material trough base (807) is slidably connected to the circumferential surface of the top side of the transmission box (802), and a screw moving groove is provided at the bottom of the material trough base (807).
8. The automatic egg beater for food processing according to claim 7, wherein The top of the large gear (805) has four spokes, which are symmetrical about each other along the vertical central axis of the support shaft (804).
9. The automatic egg beater for food processing according to claim 8, wherein The support shaft (804) and the rotating shaft (703) are located on the same vertical central axis. When the material trough base (807) is located at one end of the displacement trajectory, the bottom of the material trough (9) is not located at one end of the stirring blade of the gear shaft (70504).
10. The automatic egg beater for food processing according to claim 9, wherein The circumferential surface of the trough base (807) is fixedly connected to a limiting ring one, and the inner circumferential surface of the transmission box (802) is fixedly connected to a limiting ring two.