A smart feeder which can be conveniently disassembled and washed
By adopting a detachable design for the food dispensing blades, bottom cover, food container, and top cover, the problem of poor cleanliness in existing smart pet feeders is solved, enabling convenient disassembly, cleaning, and replacement, thus improving the user experience.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- DONGGUAN XINCHONG TECHNOLOGY CO LTD
- Filing Date
- 2025-09-30
- Publication Date
- 2026-07-14
AI Technical Summary
Existing smart pet feeders have components such as food storage parts, food dispensing covers, and food dispensing blades that are not easy to disassemble and assemble, resulting in poor cleanliness and affecting the pet's user experience.
The grain distribution blades, bottom cover, grain hopper, and top cover are designed to be detachable, and can be easily disassembled and reassembled through a snap-fit structure, making them convenient for cleaning and replacement.
It improves the cleanliness of the feeder, ensures the health of pets, facilitates parts replacement, and enhances ease of use.
Smart Images

Figure CN224482536U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of intelligent feeder technology, specifically to an intelligent feeder that can be easily disassembled and washed. Background Technology
[0002] With the improvement of living standards, more and more families in modern society are keeping pets. However, the pace of modern life is very fast, and many people cannot feed their pets when they are at work or out of the house. Most people will put food in a bowl before leaving home and let their pets eat freely. But the consequence of doing so is that the pets may overeat and not eat regularly, which can easily cause indigestion and harm their health, while also causing unnecessary trouble for the owners.
[0003] In light of this, many smart pet feeders have emerged on the market. For example, a smart pet feeder disclosed in application publication number CN114027207A specifically discloses a feeding main body, which includes a food storage component and a food dispensing component; a drive component connected to the food dispensing component for transmission; a feeding bowl located below the food inlet for receiving pet food delivered by the food inlet; a control component including a microprocessor and a wireless connection module for controlling the rotation of the drive component and connecting to external devices; and a power supply component for providing the necessary electrical energy to the drive component and the control component. The food storage component is located above the food dispensing component, which includes a food dispensing cover and a food distributing component; the drive component is located on the lower surface of the food dispensing cover; the food dispensing cover extends downward and has a mounting groove, in which the food distributing component is installed; the bottom of the mounting groove has a food dispensing port for dispensing food. The food dispensing ports and the food dispensing port are connected by a food dispensing pipe. It also includes a drive shaft extending upward from the drive assembly and passing through the grain outlet cover; the grain distributing assembly includes a grain distributing disc and a grain distributing deflector, the grain distributing disc being fixed to the upper edge of the mounting groove, and the grain distributing disc having a grain distributing opening; the end of the drive shaft above the grain distributing disc is provided with grain distributing blades; the grain distributing deflector is disposed in the cavity formed between the grain distributing disc and the mounting groove, and the grain distributing deflector is fitted onto the drive shaft. The drive assembly includes a drive motor and a reducer, the output end of the drive motor being connected to the reducer for transmission, and the output end of the reducer being connected to the drive shaft for transmission. Grain distributing guard plates are provided on both sides of the lower edge of the grain distributing opening, and corrugated toothed racks are provided on the lower edge of the grain distributing guard plates. The feeding bowl is connected and fixed to the feeding body by a snap-fit structure.
[0004] However, the aforementioned smart pet feeder also has some drawbacks. For example, the food storage components, food dispensing cover, and food dispensing blades in the smart feeder cannot be easily disassembled and cleaned. This inconvenience may affect the cleanliness of the smart feeder and make it unsuitable for pets to use.
[0005] Therefore, improvements to existing technologies are necessary. Utility Model Content
[0006] To address the problems existing in the prior art, the purpose of this utility model is to provide a smart feeder that is easy to disassemble and clean. By adopting a detachable design for the food dispensing blades, food bottom cover, food bucket, and top cover, it is easy for people to remove and clean them, which helps to ensure the cleanliness of the smart feeder and is also beneficial for pets.
[0007] To achieve the above objectives, the technical solution of this utility model is as follows:
[0008] A smart pet feeder that is easy to disassemble and wash includes a feeding body and a feeding bowl that cooperate with each other. The feeding bowl is connected to one side of the feeding body and can be used to receive pet food dispensed by the feeding body. The feeding body includes a food dispensing component located below and a food storage component located above. The food dispensing component includes a main shell with an internal mounting cavity, a food dispensing bottom cover mounted on the top of the mounting cavity and detachably connected to the sides of the main shell via a snap-fit structure, a food dispensing drive component mounted in the mounting cavity, a food dispensing blade mounted in the middle of the top surface of the food dispensing bottom cover and detachably connected to the food dispensing drive component, and a feed tube mounted on the main shell for dispensing pet food outward. The food storage component includes a food bin with two through-ends and an internal food storage space, and a top cover detachably mounted on the top of the food bin via a snap-fit structure. The food bin can be used to snap onto the top of the main shell, and the two are detachably connected via a snap-fit structure. By adopting a detachable design for the grain dispensing blades, the grain outlet bottom cover, the grain hopper, and the top cover, they can be easily removed for cleaning, which helps to ensure cleanliness.
[0009] Furthermore, one side of the feeding bowl is detachably connected to the main outer shell via a snap-fit structure, which facilitates easy assembly and disassembly.
[0010] Furthermore, the feeding bowl is connected to one side of the main outer casing via a food divider block; at least two outwardly extending food divider slots are provided on the food divider block, and at least two corresponding feeding bowls are provided; one end of each food divider slot is used to receive pet food, and the other end is used to align with the rim of the feeding bowl. This arrangement allows at least two feeding bowls to be used simultaneously, providing food for more pets.
[0011] Furthermore, the food divider block is detachably connected to the main outer shell via a snap-fit structure; each feeding bowl is also detachably connected to the food divider block via a snap-fit structure. These features facilitate the assembly and disassembly of the food divider block and feeding bowl.
[0012] Furthermore, an installation pipe is provided on the main outer casing; the feed pipe is fitted into the installation pipe, and the feed pipe and the inner wall of the installation pipe are detachably connected by a snap-fit structure. This arrangement facilitates the assembly and disassembly of the feed pipe for cleaning.
[0013] Furthermore, the grain dispensing assembly also includes a grain dispensing disc and two grain dispensing guard plates; the grain dispensing drive assembly includes a drive motor and a transmission shaft; the drive motor is fixed in the mounting cavity; the transmission shaft is mounted on the output shaft of the drive motor; the grain dispensing blade is detachably mounted on the top of the transmission shaft; the grain dispensing disc is fitted onto the transmission shaft; a grain dispensing opening that cooperates with the grain dispensing blade is provided on the grain dispensing bottom cover; the upper ends of the two grain dispensing guard plates are respectively connected to the lower edges of the grain dispensing opening on both sides, and the lower... The two food dispensing plates abut against the top surface of the food dispensing disc, forming a first food dispensing space between them. One end of the feeding tube is located inside the mounting cavity, and the other end extends out of the main outer shell for dispensing pet food. The bottom surface of the food dispensing disc abuts against a baffle inside the main outer shell. Multiple evenly distributed second food dispensing spaces, each corresponding to the first food dispensing space and the feeding tube, are located on the side wall of the food dispensing disc. A through-hole corresponding to both the second food dispensing space and the feeding tube is also provided on the baffle. This design facilitates the dispensing of pet food.
[0014] Furthermore, the grain distributing dial includes a central body mounted on the drive shaft and a plurality of levers evenly distributed on the four sides of the central body; the second grain distributing space is formed between adjacent levers.
[0015] Furthermore, the feed dispensing assembly also includes a counting wheel and a limit switch; the limit switch is fixed in the mounting cavity; the counting wheel is mounted on the drive shaft, and at least two sensing protrusions that cooperate with the limit switch are provided on the side wall of the counting wheel. With the above configuration, it can be used to detect whether there is a jam in the feeder, and the feed can be released by reversing the drive motor.
[0016] Furthermore, the latching structure between the grain bin and the top cover includes two latching blocks respectively disposed on both sides of the upper end of the grain bin, and two latches respectively disposed on both sides of the top cover and cooperating with the two latching blocks. The two latches are detachably fastened to the two latching blocks. This arrangement facilitates the assembly and disassembly of the grain bin and the top cover.
[0017] Furthermore, the snap-fit structure between the grain bin and the main outer shell includes two snap-fits respectively disposed on both sides of the lower end of the grain bin and two locking blocks respectively disposed on both sides of the upper end of the main outer shell and cooperating with the two snap-fits. The two snap-fits are detachably fastened to the two locking blocks. This arrangement facilitates the assembly and disassembly of the grain bin and the main outer shell.
[0018] The beneficial effects of this utility model are as follows:
[0019] This invention features a detachable design for the feed dispenser blades, bottom cover, feed container, and top cover, allowing for easy removal and cleaning. This ensures the cleanliness of the smart feeder and is beneficial for pets. Furthermore, the detachable design of the feed container and top cover makes them easy to replace if damaged, greatly simplifying the user experience. Attached Figure Description
[0020] Figure 1 This is a schematic diagram of the overall structure of Embodiment 1 of this utility model;
[0021] Figure 2 This is a top view of Embodiment 1 of this utility model;
[0022] Figure 3 yes Figure 2 Cross-sectional view along the middle AA;
[0023] Figure 4 This is an exploded view of Embodiment 1 of this utility model;
[0024] Figure 5 This is a schematic diagram of the internal structure of the feeding body in Embodiment 1 of this utility model. Figure 1 ;
[0025] Figure 6This is a schematic diagram of the internal structure of the feeding body in Embodiment 1 of this utility model. Figure 2 ;
[0026] Figure 7 This is a structural diagram of the second embodiment of the present invention when the number of feeding bowls is two.
[0027] Figure Labels
[0028] 1. Feeding unit; 2. Feeding bowl; 3. Discharge assembly; 31. Main outer shell; 311. Mounting cavity; 312. Perforation; 313. Baffle; 314. Locking block; 315. Installation pipe; 32. Discharge bottom cover; 321. Distributing inlet; 33. Distributing blade; 34. Distributing dial; 341. Second distributing space; 35. Distributing guard plate; 36. Feeding pipe; 37. First distributing space; 38. Counting wheel; 381. Sensing protrusion; 39. Limit switch; 40. Drive motor; 401. Transmission shaft; 4. Grain storage assembly; 41. Grain bucket; 411. Buckle; 42. Top cover; 5. Distributing block; 51. Distributing trough. Detailed Implementation
[0029] The utility model will be further described below with reference to the accompanying drawings and specific embodiments. The following description is merely exemplary and does not limit the scope of protection of the utility model.
[0030] Example 1:
[0031] like Figures 1-6 As shown, a smart feeder that can be easily disassembled and washed includes a feeding body 1 and a feeding bowl 2 that cooperate with each other.
[0032] The feeding bowl 2 is connected to one side of the feeding body 1 and can be used to receive pet food delivered by the feeding body 1.
[0033] The feeding unit 1 includes a food dispensing component 3 located at the bottom and a food storage component 4 located at the top.
[0034] like Figures 1-6As shown, specifically, the food dispensing assembly 3 includes a main outer shell 31 with an internal mounting cavity 311, a food dispensing bottom cover 32 mounted on the top of the mounting cavity 311 and detachably connected to the sides of the main outer shell 31 via a snap-fit structure, a food dispensing drive assembly mounted in the mounting cavity 311, a food dispensing blade 33 mounted in the center of the top surface of the food dispensing bottom cover 32 and detachably connected to the food dispensing drive assembly, and a feed tube 36 mounted on the main outer shell 31 for dispensing pet food outwards. The snap-fit structure between the food dispensing bottom cover 32 and the main outer shell 31 may include two slots respectively located on both sides of the food dispensing bottom cover 32 and two locking blocks respectively located on both sides of the main outer shell 31 and cooperating with the two slots. The two locking blocks are detachably engaged in the two slots, and can be unlocked by simply removing the locking blocks from the slots during use. Since the above-mentioned snap-fit structures are commonly used in the market, they will not be described in detail here. In addition, regarding the detachable structure between the grain distribution blade 33 and the grain distribution drive assembly, the grain distribution blade 33 can be directly and interference-fitted onto the grain distribution drive assembly.
[0035] like Figure 4 As shown, specifically, the grain storage assembly 4 includes a grain bin 41 with a grain storage space extending through both the top and bottom, and a top cover 42 detachably mounted on the top of the grain bin 41 via a snap-fit structure. This snap-fit structure includes two locking blocks 314 respectively located on both sides of the upper end of the grain bin 41, and two snap fasteners 411 respectively located on both sides of the top cover 42 and cooperating with the two locking blocks 314. The two snap fasteners 411 are detachably fastened to the two locking blocks 314. The grain bin 41 can be used to be snapped onto the top of the main outer shell 31, and the two are detachably connected by a snap-fit structure. This snap-fit structure includes two snap fasteners 411 respectively located on both sides of the lower end of the grain bin 41, and two locking blocks 314 respectively located on both sides of the upper end of the main outer shell 31 and cooperating with the two snap fasteners 411. The two snap fasteners 411 are detachably fastened to the two locking blocks 314. In use, the snap fastener 411 is in the unlocked state when it opens on the corresponding locking block 314. Therefore, the above-mentioned design allows for easy disassembly and assembly of the grain bin 41 and the top cover 42, facilitating cleaning, etc.
[0036] In summary, by adopting a detachable design for the feed dispensing blades 33, the feed bottom cover 32, the feed bin 41, and the top cover 42, this utility model allows for easy removal and cleaning, ensuring the cleanliness of the smart feeder and benefiting pets. Furthermore, the detachable design of the feed bin 41 and the top cover 42 makes them easily replaceable when damaged, greatly simplifying use.
[0037] In this embodiment, one side of the feeding bowl 2 is detachably connected to the main outer shell 31 via a snap-fit structure. Specifically, this snap-fit structure may include a locking block disposed on one side of the feeding bowl 2 and a locking groove disposed on the main outer shell 31 and cooperating with the locking block. The locking block is detachably engaged in the locking groove, and can be unlocked by simply removing the locking block from the locking groove during use. Since the above-mentioned snap-fit structure is a commonly used structure on the market, it will not be described in detail here. Therefore, by providing a detachable feeding bowl 2, it is convenient to remove the feeding bowl 2 for cleaning.
[0038] like Figure 1 and Figure 3 As shown, an installation pipe 315 is provided on the main housing 31; a feed pipe 36 is fitted into the installation pipe 315, and the feed pipe 36 and the inner wall of the installation pipe 315 are detachably connected by a snap-fit structure. Specifically, the snap-fit structure may include a protrusion (not shown) on the outer wall of the feed pipe 36 and a groove (not shown) on the inner wall of the installation pipe 315 that mates with the protrusion. The feed pipe 36 can be positioned in the installation pipe 315 by the engagement of the protrusion and the groove. In addition, when you want to remove the feed pipe 36, you only need to pull the feed pipe 36 outwards, and when installing, you can push the feed pipe 36 directly into the installation pipe 315 until the protrusion and the groove engage. In this embodiment, protrusions are provided on both outer walls of the feed pipe 36, and grooves are correspondingly provided on both inner walls of the installation pipe 315. Therefore, the above-mentioned setup facilitates the disassembly and assembly of the feed tube 36, enabling the feed tube to be disassembled and cleaned.
[0039] In this embodiment, the grain dispensing component 3 further includes a grain dispensing disc 34 and two grain dispensing guard plates 35; the grain dispensing drive component includes a drive motor 40 and a transmission shaft 401.
[0040] like Figure 5 and Figure 6 As shown, the drive motor 40 is fixed in the mounting cavity 311; the transmission shaft 401 is mounted on the output shaft of the drive motor 40; the grain distribution blade 33 is detachably mounted on the top of the transmission shaft 401, and the two can be detachably mounted by means of an interference fit.
[0041] like Figures 3-6 As shown, the food dispensing disc 34 is mounted on the drive shaft 401; a food dispensing port 321 that cooperates with the food dispensing blade 33 is provided on the food outlet cover 32; the upper ends of the two food dispensing guard plates 35 are respectively connected to the lower edges of the food dispensing port 321, and the lower ends respectively abut against the top surface of the food dispensing disc 34, forming a first food dispensing space 37 between the two food dispensing guard plates 35. One end of the feed pipe 36 is located in the mounting cavity 311, and the other end extends out to the outside of the main housing 31 for dispensing pet food;
[0042] like Figures 3-6 As shown, the bottom surface of the food dispensing disc 34 abuts against a baffle 313 inside the main outer shell 31. Multiple evenly distributed second food dispensing spaces 341, each cooperating with the first food dispensing space 37 and the feeding pipe 36, are located on the side wall of the food dispensing disc 34. Specifically, there are three second food dispensing spaces 341. A perforation 312, cooperating with both the second food dispensing spaces 341 and the feeding pipe 36, is also provided on the main outer shell 31 to allow pet food in the second food dispensing spaces 341 to fall into the feeding pipe 36. Therefore, after receiving pet food from the first food dispensing space 37, the rotation of the food dispensing disc 34 allows the pet food in the second food dispensing space 341 to be fed to the perforation 312 and then fall into the feeding pipe 36, ultimately being discharged outwards.
[0043] like Figure 5 As shown, in this embodiment, the grain distributing disc 34 includes a central body mounted on the drive shaft 401 and a plurality of levers evenly distributed on the surrounding side walls of the central body; a second grain distributing space 341 is formed between adjacent levers. Since the structure of the grain distributing disc 34 is prior art, it will not be described in detail here.
[0044] like Figure 6 As shown, specifically, the feed dispensing assembly 3 also includes a counting wheel 38 and a limit switch 39; the limit switch 39 is fixed in the mounting cavity 311; the counting wheel 38 is mounted on the drive shaft 401 and at least two sensing protrusions 381 that cooperate with the limit switch 39 are provided on the side wall of the counting wheel 38. In this embodiment, three sensing protrusions 381 are evenly distributed. When the drive motor 40 drives the drive shaft 401 to rotate, it can also synchronously drive the counting wheel 38 to rotate, that is, the sensing protrusions 381 will rotate. At this time, if the limit switch 39 cannot guarantee that it contacts each sensing protrusion 381 once within a unit time (e.g., within 3 seconds) (for example, the limit switch 39 can only contact two of the sensing protrusions 381), then a situation of food jamming may occur between the bottom surface of the feed dispensing disc 34 and the baffle 313. Then, the output shaft of the drive motor 40 will reverse a certain distance to release the jammed pet food. Then, after the output shaft of the drive motor 40 reverses for a certain period of time, it will rotate forward again to continue feeding until all three sensing protrusions 381 have completed contact sensing with the limit switch 39, that is, the pet food has been delivered to the feed tube 36. Therefore, with the above settings, it can be used to detect whether there is a food jam in the feeder, and the reverse rotation of the drive motor 40 can be used to release the food, which is highly practical.
[0045] Of course, this utility model also includes a circuit board (not shown in the figure) that serves as a control center, which is electrically connected to the drive motor 40.
[0046] The following describes the detailed operating principle of this utility model in order to help you understand it:
[0047] First, after pet food is loaded into the food container 41, the pet food falls onto the food outlet cover 32. Next, the drive motor 40 drives the transmission shaft 401 to rotate, simultaneously rotating the food dispensing blades 33, the food dispensing dial 34, and the counting wheel 38. Next, the food dispensing blades 33 drop the pet food from the food dispensing opening 321 into the first food dispensing space 37 between the two food dispensing guards 3535. Then, as the food dispensing dial 34 continues to rotate, when the second food dispensing space 341 aligns with the first food dispensing space 37, the pet food falls from the first food dispensing space 37 into the second food dispensing space 341. Next, the food dispensing dial 34 continues to rotate, and when the second food dispensing space 341 containing the pet food aligns with the perforation 312, the pet food passes through the perforation 312 and falls into the feed pipe 36, and is finally delivered to the feeding bowl 2 for the pet to eat. This completes one pet food dispensing cycle. Simultaneously, as the food dispensing disc 34 rotates, the counting wheel 38 rotates synchronously. Next, during a single pet food dispensing cycle, if all three sensing protrusions 381 are detected by the limit switch 39, it indicates that the intelligent feeder is in normal working order. When pet food cannot be dispensed smoothly, i.e., when food gets stuck between the food dispensing disc 34 and the baffle 313, and not all three sensing protrusions 381 are detected sequentially by the limit switch 39, the output shaft of the drive motor 40 will automatically reverse a certain distance to release the stuck material. Then, after the output shaft of the drive motor 40 reverses for a certain period, it can rotate forward again until the pet food is dispensed. Of course, if feeding cannot be completed within a long time, the drive motor 40 will stop to avoid damaging the machine. Additionally, a warning light (not shown in the figure) can be installed on the main casing 31 to alert users when food jams occur and cannot be resolved.
[0048] Example 2:
[0049] like Figure 7As shown, the difference between this embodiment and Embodiment 1 is that in this embodiment, the feeding bowl 2 is connected to one side of the main outer shell 31 via a food divider 5; moreover, at least two outwardly extending food divider troughs 51 are provided on the food divider 5, and at least two corresponding feeding bowls 2 are provided; one end of each food divider trough 51 is used to receive pet food (specifically, pet food delivered by the feed tube 36), and the other end is used to align with the rim of the feeding bowl 2. Therefore, the above arrangement allows for the convenient provision of at least two feeding bowls 2 outside the feeding body 1, so that at least two pets can use them simultaneously. In this embodiment, the number of food divider troughs 51 and feeding bowls 2 is two.
[0050] In this embodiment, the feeding block 5 and the main outer shell 31 are detachably connected via a snap-fit structure. This snap-fit structure may include a slot on the side wall of the main outer shell 31 and a locking block on the side wall of the feeding block 5 that engages with the slot. The locking block is detachably engaged in the slot, and can be unlocked by simply removing it from the slot. Each feeding bowl 2 is also detachably connected to the feeding block 5 via a snap-fit structure. This snap-fit structure may also include a locking block on one side of the feeding bowl 2 and a slot on the feeding block 5 that engages with the locking block. The locking block is detachably engaged in the slot, and can be unlocked by simply removing it from the slot. Since these snap-fit structures are commonly used in the market, they will not be elaborated upon here. Therefore, the above design facilitates the assembly and disassembly of the feeding block 5 and the feeding bowl 2 for cleaning and other purposes, making it very convenient to use.
[0051] This utility model is not limited to the above-described embodiments. If any modifications or variations to this utility model do not depart from the spirit and scope of this utility model, and if such modifications and variations fall within the scope of the claims and equivalent technologies of this utility model, then this utility model also intends to include such modifications and variations.
Claims
1. A smart feeder that is easy to disassemble and wash, characterized in that: This includes a feeding device and a feeding bowl that work together; The feeding bowl is connected to one side of the feeding body and can be used to receive pet food fed by the feeding body. The feeding unit includes a food dispensing component located at the bottom and a food storage component located at the top; The food dispensing assembly includes a main outer shell with an internal mounting cavity, a food dispensing bottom cover mounted on the top of the mounting cavity and detachably connected to the sides of the main outer shell via a snap-fit structure, a food dispensing drive assembly mounted in the mounting cavity, a food dispensing blade mounted in the middle of the top surface of the food dispensing bottom cover and detachably connected to the food dispensing drive assembly, and a feeding pipe mounted on the main outer shell for dispensing pet food outward. The grain storage assembly includes a grain hopper with two through-ends and an interior space for storing grain, and a top cover that is detachably mounted on the top of the grain hopper via a snap-fit structure; the grain hopper can be snapped onto the top of the main outer shell and the two are detachably connected via a snap-fit structure. The grain separating blades, the grain outlet bottom cover, the grain bucket, and the top cover are all designed to be detachable, which makes them easy to remove and clean, thus ensuring cleanliness.
2. The easily detachable and washable intelligent feeder according to claim 1, characterized in that: The feeding bowl is detachably connected to the main outer shell via a snap-fit structure on one side.
3. The easily detachable and washable intelligent feeder according to claim 1, characterized in that: The feeding bowl is connected to one side of the main outer shell via a food divider block; at least two outwardly extending food divider slots are provided on the food divider block, and at least two corresponding food divider slots are provided on the feeding bowl; one end of each food divider slot is used to receive pet food, and the other end is used to align with the rim of the feeding bowl.
4. The easily detachable and washable intelligent feeder according to claim 3, characterized in that: The food divider block is detachably connected to the main outer shell via a snap-fit structure; each feeding bowl is also detachably connected to the food divider block via a snap-fit structure.
5. The easily detachable and washable intelligent feeder according to claim 1, characterized in that: An installation pipe is provided on the main housing; the feed pipe is fitted through the installation pipe and is detachably connected to the inner wall of the installation pipe by a snap-fit structure.
6. The easily detachable and washable intelligent feeder according to claim 1, characterized in that: The grain dispensing assembly also includes a grain dispensing disc and two grain dispensing guard plates; the grain dispensing drive assembly includes a drive motor and a transmission shaft; The drive motor is fixed in the mounting cavity; the transmission shaft is mounted on the output shaft of the drive motor; the grain distributing blade is detachably mounted on the top of the transmission shaft; The grain distributing disc is mounted on the drive shaft; a grain distributing opening that cooperates with the grain distributing blade is provided on the grain outlet bottom cover; the upper ends of the two grain distributing guard plates are respectively connected to the lower edges of the grain distributing opening, and the lower ends respectively abut against the top surface of the grain distributing disc, forming a first grain distributing space between the two grain distributing guard plates; One end of the feeding tube is located inside the mounting cavity, and the other end extends out to the outside of the main outer shell for dispensing pet food. The bottom surface of the grain dispensing disc abuts against a baffle inside the main housing; the side wall of the grain dispensing disc has a plurality of evenly distributed second grain dispensing spaces that respectively cooperate with the first grain dispensing space and the feeding pipe; the baffle is also provided with a perforation that corresponds to the second grain dispensing space and the feeding pipe respectively.
7. The easily detachable and washable intelligent feeder according to claim 6, characterized in that: The grain distribution dial includes a central body mounted on the drive shaft and multiple levers evenly distributed on the four sides of the central body; the second grain distribution space is formed between adjacent levers.
8. The easily detachable and washable intelligent feeder according to claim 6, characterized in that: The grain dispensing assembly also includes a counting wheel and a limit switch; the limit switch is fixed in the mounting cavity; the counting wheel is mounted on the drive shaft and at least two sensing protrusions that cooperate with the limit switch are provided on the side wall of the counting wheel.
9. The easily detachable and washable intelligent feeder according to claim 1, characterized in that: The buckle structure between the grain bin and the top cover includes two buckles respectively disposed on both sides of the upper end of the grain bin and two buckles respectively disposed on both sides of the top cover and cooperating with the two buckles. The two buckles are detachably fastened to the two buckles.
10. The easily detachable and washable intelligent feeder according to claim 1, characterized in that: The buckle structure between the grain bin and the main outer shell includes two buckles respectively disposed on both sides of the lower end of the grain bin and two locking blocks respectively disposed on both sides of the upper end of the main outer shell and cooperating with the two buckles. The two buckles are detachably fastened to the two locking blocks.